4               Land Contamination

Introduction

4.1           As detailed in the Theme Park EIA, Cheoy Lee Shipyard (CLS) located on the north and eastern shores of Penny’s Bay, was identified as the primary land use of concern for land contamination.  Additionally, the decommissioning of CLS comprises a Designated Project under Schedule 2 of the EIAO.  To allow the Theme Park and associated infrastructure development, CLS should be decommissioned and properly remediated. As such, site investigation (SI) at CLS is necessary.

4.2           Site investigation was split into two distinct phases (Advanced SI and Phase 2 SI) due to site access limitation in the earlier phase of the project.  The advanced SI, which included the advancement of 13 boreholes, was carried out with the consent of shipyard occupier between November and December 2000 when the site was under private ownership and was yet to be resumed by HKSAR Government. 

4.3           The advanced SI identified a number of locations at the shipyard site having signs of soil and groundwater contamination.  Due to access restriction, the extent of contamination could not be quantified at that time.  Detailed Phase 2 SI was recommended be carried out throughout the whole site after resumption of the shipyard.

4.4           After the resumption of the subject shipyard in April 2001, the Phase 2 SI at the former CLS site for the preparation of the EIA report was commenced in June 2001 and was completed in November 2001.  The Phase 2 SI was carried out in accordance with the Contamination Assessment Plan (CAP), which had been approved by EPD.

4.5           The primary area addressed by the SI is the former location of the CLS, situated at the head of and along the eastern shore of Penny’s Bay.  The CLS site comprises approximately 18.7 hectares of primarily reclaimed land along the bay waterfront.  The CLS used the site for construction and repair of fiberglass (also known as glass reinforced plastic or GRP), wooden, aluminium, and steel-hulled ships from 1963 until 2000.

4.6           The outlines of the approved CAP and the content of the Contamination Assessment Report (CAR) and the Remediation Action Plan (RAP) are presented in this chapter.

4.7           On the issue of land contamination, URS Corporation (URS) in association with BMT Asia Pacific (BMT), collectively referred as the Independent Environmental Consultant (IEC), have conducted separate environmental assessment and remediation assessment at the CLS site.  Their inputs to the land contamination process include designing the Remedial Investigation Work Plan (RIWP), providing oversight for the site investigation works, independent assessment on the nature and extent of contamination, evaluation of the risks and recommendation on-site clean up measures.  The IEC’s report summarising their independent findings is annexed in Appendix 4I.           

Environmental Legislation, Policies, Plans, Standards and Criteria

4.8           The SI has been conducted following HKSAR Environmental Protection Department’s (EPD’s) Practice Note for Professional Persons, Contaminated Land Assessment and Remediation (ProPECC Note PN 3/94) and EPD’s Guidance Notes for Investigation and Remediation of Contaminated Sites of Petrol Filling Stations, Boatyards, and Car Repairing/ Dismantling Workshops and the U.S. Environmental Protection Agency’s (USEPA’s) Guidance for Conducting Remedial Investigations and Feasibility Studies under CERCLA.

4.9           Hong Kong environmental guidelines make reference to criteria (Dutch List) developed in the Netherlands, which are comprehensive and widely used for contaminated site assessment.  However, numerous chemicals analysed are not included in the Dutch List.  As such, in the present assessment, a hierarchy of action levels and/or cleanup standards was adopted.  In order of priority, these include the following 3 types of standards:

i)      Dutch “B” standards;

 

ii)    If there is no Dutch “B” standard for a certain chemical, U.S. Environmental Protection Agency (USEPA) federal standard was adopted (e.g. Soil Screening Levels (SSL) published under Soil Screening Guidance : Technical Background Document);

 

iii)   If there is no USEPA federal standard, USEPA Region IX Preliminary Remediation Goal (PRG) was used. The USEPA Region IX PRGs are adopted because they are more comprehensive compared with other USEPA regional standards.

Dutch Guidelines

4.10        The Dutch criteria consist of three levels of standards for a range of soil and groundwater contaminants, representing the following three scenarios:

§                A – level implies unpolluted;

§                B – level implies potential pollution present and requires further investigation or remediation; and

§                C – level implies pollution, which requires remediation.

4.11        The Dutch guidelines are very stringent as they are developed based on a ‘good for all uses’ philosophy.  The EPD generally requires remediation for soil contamination above the Dutch ‘B’ Standards.  In other words, the Dutch ‘B’ standards are the clean-up target for remediation of soil. 

USEPA Federal Standard

4.12        The USEPA federal standard contains generic Soil Screening Levels (SSLs) for 110 chemicals.  The generic SSL are derived using default values in standardised equations.  The default values are conservative and are likely to be protective for the majority of site conditions across the nation.  It should be noted that for some chemicals, there are four SSL representing four pathways, namely direct ingestion, inhalation, migration to groundwater (with dilution-attenuation factor of 20) and migration to groundwater (no dilution-attenuation).  For each chemical, the SSL for ingestion or for inhalation, whichever is lower, was used for screening.     

USEPA Region IX PRGs

4.13        PRGs, risk-based concentrations taking into account of exposure pathway and toxicity data, are tools for evaluating and cleaning up contaminated sites in U.S. Environmental Protection Agency (USEPA) Region IX Superfund sites.  Two PRGs are applicable for soil medium, namely residential soil and industrial soil.  In this SI, for conservative approach, the PRGs for residential soil are adopted as the action levels for chemicals not included in Dutch guidelines.  Please refer Appendix 4A for the action levels for soil remediation.  

Risk-based Criteria for Groundwater

4.14        The Dutch standards for groundwater and the USEPA Region IX PRGs for tap water are not directly applicable in assessing the groundwater contamination in Hong Kong, where groundwater is not a source of potable water.  (The USEPA federal standard does not contain groundwater screening levels).  As such, the Dutch ‘B’ standards and the USEPA Region IX PRGs for tap water are only for screening out the chemicals of concern for risk assessment and are not for assessing groundwater contamination in Hong Kong.  A risk-based assessment would be carried out for chemicals with concentration exceeding the Dutch ‘B’ standards or the USEPA Region IX PRGs for tap water if there is no Dutch ‘B’ standard for a certain chemical to evaluate the risks posed to the sensitive receptors.  The risk-based assessment that has been adopted in USEPA takes into account concentrations of individual contaminants in groundwater, the anticipated most sensitive human receptor and the potential exposure pathways.  For a worst-case scenario, the largest contaminant concentrations in the groundwater samples would be taken as the source concentration for the risk calculation. 

4.15        Exceedance of the risk-based criteria would be qualified in two tiers. For noncarcinogens, the first is the Total Pathway Hazard Index (TPHI) that is the sum of contaminant hazard quotients exceeds one.  The second is the largest contaminant concentration exceeds the corresponding Risk-based Screening Level (RBSL) that is derived from the recognised oral reference dose.  For carcinogens, the first is the Total Carcinogenic Risk that is the sum of contaminant carcinogenic risk exceeds 1 x 10-6.  The second is the largest carcinogenic contaminant concentration exceeds the corresponding RBSL that is derived from the recognised carcinogenic slope factor.

Action Level / Cleanup Target for Dioxins

4.16        The USEPA’s OSWER Directive 9200.4-26 (“Approach for Addressing Dioxin in Soil at Comprehensive Environmental Response, Compensation, and Liability Act (CERCLA) and Resource Conservation and Recovery Act (RCRA) Sites” signed 13 April 1998) states that 1 ppb Toxicological Equivalence Quotient (TEQ) is generally recommended as a cleanup target for dioxins for residential soils at CERCLA and RCRA sites (5 to 20 ppb TEQ has been selected for industrial use scenarios).  As such, 1 ppb TEQ is used as both the action level and cleanup target for dioxins in the present study.    

Universal Treatment Standards

4.17        For metal contaminants to be remediated by solidification, the Universal Treatment Standards (UTS) of U.S. Resource Conservation and Recovery Act (RCRA) wastes that contain metals (in 40 CFR 268) should be referred.  These standards were derived from the performance of the Best Demonstrated Available Technologies for treating these types of wastes.

4.18        Treating dioxin-contaminated soil to 1 ppb TEQ would meet the Universal Treatment Standards (UTS) and would be consistent with USEPA’s OSWER Directive 9200.4-26.  In Hong Kong, the UTS standards have been applied to the acceptance criteria of metal contaminated soil treatment

Site Setting and Physical Characteristics of Study Area

Overview

4.19        The most detailed information available regarding site land use and former operations at the CLS site at Penny’s Bay is contained in the Final Environmental Impact Assessment Report for Lantau Port Development—Stage 1, Reclamation for Shipyard at To Kau Wan, North Lantau, EIA for Operational Phase prepared by Binnie Consultants Limited (BCL, October 1995).

4.20        According to BCL, Cheoy Lee Shipyards Limited established their Penny’s Bay shipyard in 1963 on reclaimed land leased from the Government.  Over the years of operation, the CLS site was expanded, with additional land reclamation to the southeast of the original site.  CLS’ shipbuilding business consisted of three main activities: fiberglass or glass-reinforced plastic (GRP) boat manufacture, metal (usually steel or aluminium) boat manufacture, and boat repair and maintenance.  Historically, CLS manufactured wooden-hulled boats, and the sawmill operations and building were present until plant operations ceased.  CLS’s boat-building operations included complete fabrication from raw materials to the finished product, which minimised purchase of components from other suppliers.

4.21        Ships and boats fabricated at the CLS site ranged from small launches to ocean-going yachts, passenger ferries, tugs and luxury pleasure craft.  Vessels up to 80 meters (260 feet) in length were constructed at the site.

4.22        The boat repair and maintenance aspect of Cheoy Lee’s business included general repair of boat hulls and superstructures, shot blasting of boat hulls, re-painting, and the repair, or removal for renovation, of marine engines.

4.23        The Penny’s Bay Shipyard layout evolved over time and was modified to suit changing demand.  CLS increased the size of the shipyard land area with further reclamation by quarrying the hillside to provide the materials for reclamation.  According to the Final EIA Report by BCL (1995), the reclaimed area used by CLS at the time the EIA was prepared totaled approximately 14 hectares (34.6 acres); of which about 4.2 hectares (10.4 acres) was occupied by buildings, 2.1 hectares (5.2 acres) for the storage of fiberglass boat molds and 7.5 hectares (18.5 acres) of open areas and roads for access, cranes, storage, maneuvering, slipways and open-air boat fabrication.

Site Details

4.24        The CLS site was divided into three areas:  Area 1 consists of the northern part of the site that was the original CLS facility; Area 2 includes the central part of the site that was formed by land reclamation following initiation of shipbuilding operations by CLS within Area 1; and Area 3 includes the southeastern portion of the site, which is located on the most recent part of reclaimed land.

Area 1

Building A—Company Store

4.25        This building is approximately 9 by 46 metres (30 by 150 feet) in size and appears to have been used for dry goods storage, including various boat/ship fittings and components.

Building B—Plating, Anodising and Laboratory

4.26        The building was used by CLS for metals electroplating and anodising.  It also has a small quality control testing laboratory.  An office was also present in the southwestern corner of the building.  The building is approximately 19 by 67 metres (62 by 220 feet) in size.

4.27        Chemicals that are used in the plating and anodising process are included:

·       Copper cyanide;

·       Sodium hydroxide;

·       Sodium carbonate;

·       Nickel chloride;

·       Boric acid;

·       Chromic acid;

·       Sulphuric acid;

·       Phosphoric acid; and

·       Nitric acid.

4.28        Various other chemicals may have been used, such as trisodium phosphate of sodium carbonate during the alkali wash, or ammonia to neutralise the wastewater.

4.29        From the chemicals listed above, cyanide and hexavalent chromium are probably of greatest concern due to their known acute toxicity.  Other chemicals used were either very corrosive, such as acids and alkalis, or toxic, such as nickel or copper solutions.  The plating and anodising operations were carried out as a batch process and that all of the plating and acid baths did not discharge waste into the drainage system but were either continually topped up with fresh chemicals or, when potency of the solution fell below that required, poured into a container for disposal.

4.30        The waste discharge from each of the washing processes were reportedly collected in a large underfloor “diffuser” before being discharged to the drainage system.  The drainage discharge reportedly was monitored for pH, nickel, copper, iron, cyanide and phosphorus by the in-house laboratory so as to comply with the discharge regulations specified in CLS’ Water Pollution Control Ordinance License.

4.31        The laboratory present in this building was used to measure the quality of metals formed in the foundry and to monitor the quality of solutions and effluent from the electroplating and anodising operations.

Building C—Warehouse

4.32        The warehouse was reported by BCL to have been used for dry goods storage.  The building is approximately by 9 by 46 metres (30 by 150 feet) in size and contains a mezzanine level of steel construction over approximately one-half of the building.  The building appeared to have a fairly new roof and floor, suggesting it had been remodelled.

Building D—Hull Moulding and Pressing Workshop, Aluminium Smelter

4.33        Building D is a large multi-use building that has been compartmentalised with interior walls separating different use areas.  The building was originally two separate buildings with an intervening open-air passageway.  The passageway was subsequently roofed over and a concrete floor placed to create one building.  Overall, the building is approximately 43 by 46 metres (140 by 150 feet) in size.

4.34        Storage and an office area were located on the eastern part of the building.  An aluminium smelter, document storage area and an office was located on the second bay from eastern of the building.  The smelter area at the rear contain a crucible furnace with a hood and venting system.  The furnace was apparently fuelled with diesel fuel and is supplied by an aboveground diesel tank mounted on the wall adjacent to the furnace.  A die-casting and metal stamping area was situated at central part of the building.  A small-scale fiberglassing and pipe storage was located in the western part of this building. 

Building E and F—Security Guards Quarters and Staff Canteen

4.35        Building E and F are approximately 6 by 32 metres (20 by 105 feet).  These buildings are served as site security guards quarters and a staff canteen for resident CLS staff.

Building G—Worker’s Canteen

4.36        This building served as the kitchen and dining area for the CLS workers.  The main environmental concern may be associated with food waste and oil and grease.

Building H—Dangerous Goods Stores

4.37        Building H consists of two parts.  This is a row of six 3-metre square (10 feet by 10 feet) concrete-constructed dangerous goods lockers along one side and a partially depressed larger storage area that measures approximately 9 by 10 meters (30 by 35 feet) to the rear.

4.38        The dangerous goods lockers were constructed with walls on the order of 30 cm (1 foot) thick and a 0.5 m (1.5 feet) high door sill that provided secondary containment.  The lockers were contained as labelled, from east to west, MEKP, paints, oxygen (O2), paints, sulphuric and acetylene.

4.39        The building to the rear has an elevated loading dock approximately 1 meter (3.3 feet) above ground level with stairs leading down approximately 2.5 metres (8 feet) to a concrete floor. This area is used to store fiberglass resins. 

Building I—Machine Shop

4.40        The machine shop is an approximately 18 by 32 meters (60 by 105 feet) in size and consists of two bays.   Two diesel fuel-fired crucible furnaces were located in the northern bay.  A tool and parts storage room and another open area of unknown past use is located at the southern bay.  Stamping steel, fabrication and assembly of various components may be processed in this area.

Building J—Lost Wax Store

4.41        Lost wax store is a small, approximately 9 by 18 metres (30 by 60 feet) two-storey building located adjacent to the machine shop and foundry.  A small crucible furnace, a mould curing area, and three apparent dip tanks and a number of propeller molds were located in the in the first floor.  Storage of welding electrode is the main purpose for second floor.

Building K—Fiberglass Hull Construction Workshop

4.42        This large building is approximately 43 by 46 metres (140 by 150 feet) in size and was formerly used for laying up of fiberglass boat hulls.  It has an open-plan construction with interior columns supporting the roof and a concrete floor.

Building L—Foundry

4.43        The foundry building is approximately 18 by 46 metres (60 by 150 feet) in size and is a large, open bay building.  A large induction furnace for stainless steel production, three smaller diesel-fuelled crucible furnaces, three large annealing furnaces and a burn pit were located in the building. 

4.44        An aboveground tank mounted on the exterior building supplied diesel to the three crucible furnaces.  The annealing furnaces were fuelled with diesel fed from aboveground tanks adjacent to the furnaces.  A burn pit with burned wood and ashes with approximately 2 meters (6.5 feet) was located in the building.  

Building M—Former Rolling Mill

4.45        Building M was formerly used for rolling of metal sheets for fabrication of steel-hulled vessels.  This building was dismantled sometime prior to 1991.  The area has been used as a scrap yard.

Building N—Metal Stamping Building (a.k.a. Hammer Room)

4.46        The building N is approximately 9 by 14 metres (30 by 45 feet) building that contained a remnant foundation from heavy machinery. 

Building O—Sawmill and Moulding Shed

4.47        The building is approximately 24 by 73 metres (80 by 240 feet).  It consists of two parts, sawmill and moulding shed, separated by a wall down its long axis.  It was equipped with wood milling equipment.

Building P—Leather Dressing, Stores, and Vehicle Maintenance Shed

4.48        This building is approximately 15 by 37 metres (50 by 120 feet).  The building served for  two activities, vehicle maintenance and leather dressing and stores.  The vehicle maintenance shed occupied an area roughly 6 by 15 metres (20 by 50 feet).  The leather dressing and stores part is a two-storey building. 

Fuelling and Loading Area along Seawall

4.49        There was an area adjacent to the seawall at the southeast end of Buildings A, B, P and O being used for salvage and for loading of these materials onto barges for offsite shipment.

Area 2

Building R—Fiberglass Boat Finishing (Yacht Building)

4.50        This open-plan building is approximately 47 by 47 metres (154 by 154 feet) in size.  It has a very high roof and a roof drain system connected to the perimeter drain system.  The building was used for fiberglass boat finishing.

Building S—Boat Finishing (Yacht Building)

4.51        The building is approximately 43 by 70 metres (140 by 230 feet) in size and has a high-roof.  A row of office, tool crib, and speciality rooms was located in the building.

Building T—Boat Finishing and Painting Building

4.52        The building is compartmentalised and is approximately 33 by 70 meters in size.  This building was used for painting and drying of shipbuilding components and yachts, yacht finishing and plumbing and joinery.  Besides, some areas are used as offices, storage of fitting, piping and other materials and solvent still area.

Building U—Fire Suppression Pump House

4.53        The building is small and is located adjacent to the seawall near the slipway in the central part of the site.  A diesel powered engine and pump for firefighting   were located in the building.

Building V—Mould Lofting Room, Paint Booth, and Mould Mock-up Building

4.54        The building is approximately 41 to 44 metres by 70 metres (135 to 145 by 230 feet).  The building contained a mould lofting room, paint spray booth and wood mould mock-ups.

Building W-Welding/Metal Workshop

4.55        Building W is an approximately 25 by 25 metres (82 by 82 feet) open building.  It was used for welding and metal works, like grinding and steel fabrication.  It contained a transfer room.

Building X—Shot-blasting Building

4.56        Building X is approximately 11 metres wide by 26 metres long (35 by 85 feet).  It is located adjacent to the welding/metal workshop.  Shot-blasting was processed in the building to make a clean surface for finishing.

Building Y—Metal Workshop/Hull Finishing Building

4.57        The building is approximately 19 by 58 metres (63 by 190 feet).  It was used for welding and fabrication of steel-hulled vessels.

Building Z—Metal Boat/Metal Sheet Fabrication Building

4.58        Building Z is approximately 19 by 43 metres (62 by 140 feet) and open at both ends.  The building had an office-like enclosure or tool crib.

Slipway and Boat Launch

4.59        A boat slipway (launch ramp) was located adjacent to the pump house (Building U).  It has an elevated ramp north of the slipway near the northern end of Building Y.

Area 3

Building Q—Boat Repair Building and Area

4.60        This building is located at the southeastern area of the site adjacent of two parallel slips for docking of vessels.  Maintenance and repair of vessels was performed in this area.  Several sheds and a long rectangular building were used to store various paints and solvents used in boat maintenance and refinishing.  Paint chipping as preparation for painting was also performed in this area.  Some engine or other mechanical equipment maintenance and repair was located in the building.

Hull Mould Storage Area

4.61        The area extending from the base of the hills behind Building S southeastward to the fence line was used by CLS to store fiberglass hull molds.  Based on review of aerial photographs taken in 1991, more than 125 molds of various sizes and configurations were stored in this area of the site.

Identification of Sensitive Receivers

4.62        Typical land uses to be considered as sensitive receivers include residential gardens and grassed public areas, such as parks and playgrounds.  No such sensitive receivers are represented in our assessment area.  There are no agricultural or groundwater wells in the subject shipyard to create two potential contaminant exposure pathways, namely produce and potable water.  This situation affords little exposure of aboveground population to underlying soil.  Consequently the identification of sensitive receivers will be dependent both upon the locations of the redevelopment of existing sites and when this will take place, and upon the proposed end use of the land.

4.63        Any contaminated soil and groundwater found within the site will be remediated and any such remediation system will be effectively mitigated so as to prevent any potential negative impact.  No contaminated soil and groundwater is likely to remain after remediation to the agreed cleanup targets and satisfaction of EPD.  As such, land contamination at CLS will not adversely affect the Theme Park development and will not pose significant heath threat to the future users of the site.

4.64        Compared to the future land users, construction workers will be more exposed to the contaminated material during excavation and remediation works.  Therefore, mitigation measures for workers’ health and safety should be addressed.  The principal exposure routes for workers include:

§                Direct ingestion of contaminated soils through eating or drinking on site; and

§                Dermal contact with contaminated spoil during earth moving operations and excavation.

§                Inhalation of dust (from soil).

Assessment Methodology

4.65        The objectives of the SI are to:

i)      Identify sources of contamination beneath the CLS site;

ii)    Define the presence, nature, and concentrations of contaminants in soil and groundwater beneath the CLS site and establish their vertical and lateral extents;

 

iii)   Evaluate the potential risk to humans and the environment posed by the identified soil and groundwater contamination; and

 

iv)   Establish cleanup levels for contaminants identified to be present at concentrations that exceed appropriate risk-based criteria.

 

4.66        The following tasks have been undertaken:

§                Review of the current and historical land uses of the shipyard to evaluate the likelihood of contamination.

§                Description of the nature and extent of contamination based on the available analytical data.

§                Recommendations of appropriate and cost-effective remediation strategy to cleanup the site. 

Soil Boring and Sampling

4.67        For buildings with limited use of chemicals and no apparent signs of contamination, limited soil borings were planned to provide site coverage.  However, extensive sampling and testing were conducted in areas where significant use of chemical was expected and visual signs of contamination were noted.  For areas with access limits of drilling equipment or where shallow impacts are of concern, soil samples were collected at depths of 0.15m, 0.75m and 1.5m below ground surface (bgs).  In areas where liquid chemical or fuel hydrocarbon releases are of concern, samplings were proceeded at 3m and 4.5m bgs. 

Exploratory Trenching

4.68        The southeastern area of the site formerly used for hull mould storage, and where burn pits are suspected and disposal to open trench was observed, a phased approach consisting of geophysical surveys and trenching were carried out.  Geophysical survey (i.e. employing electromagnetic ground conductivity mapping, magnetic mapping, and ground penetrating radar profiling) exploring subsurface anomalies indicative of past disposal activities was conducted by a Geophysical Surveying Contractor.  Areas identified with geophysical anomalies were explored by excavation, visual inspection, logging, and sampling in a series of trenches by backhoe. 

Groundwater Investigation

4.69        Impacts to groundwater were assessed by installing, developing and sampling at groundwater monitoring wells. 

Soil Analytical Programme

4.70        Metals, Total Petroleum Hydrocarbons (TPH), Volatile Organic Compounds (VOCs), Semi-volatile Organic Compounds (SVOCs), pH and cyanide were tested for in all samples.  Hexavalent chromium was tested at selected locations.  Polychlorinated Biphenyls (PCBs) were tested soil samples taken at locations where electrical equipment or oil heating bath which might use PCB-containing oil.  Dioxins were tested in apparent burning areas.  Tributyltin (TBT) was tested in areas where metal-hulled boats were constructed or repaired.  Testing of pesticides and herbicides were done in areas where such chemicals might have been used to control vermin and weed. 

4.71        In addition to the above chemical testing, physical parameters such as moisture content, bulk and grain density, effective and air filled porosity, total organic carbon (TOC), and permeability and hydraulic conductivity were tested at the locations of groundwater monitoring wells for evaluating the fate and mobility of contaminants. 

Groundwater Analytical Programme

4.72        Similar to the above soil analytical programme, cations/ anions and natural attenuation parameters were added to selected groundwater samples.

4.73        For the details of the SI methodology, please refer to the approved CAP, which has been approved by EPD.

Identification of Environmental Impacts

4.74        Land contamination can cause polluted groundwater and contaminated soil.  The decontamination/ remediation process(es) can also cause air quality impacts, waste arising, and health and safety to construction workers.  The environmental impacts due to land contamination and decontamination have been addressed in air quality, water quality, waste management, and ecological impact sections. 

Evaluation of Environmental Impacts

Fieldwork and On-site Measurements

4.75        The field work (soil and groundwater sampling) of the site investigation was undertaken in accordance with the sampling schedule detailed in the approved CAP by the drilling contractor.  A total number of 316 boreholes and 33 groundwater wells, and 3.1-km of trial trenches have been completed.  Furthermore, 127 additional boreholes and 23 additional groundwater wells were completed.  For the total 57 trenches excavated, groundwater sampling was undertaken at 15 of them.  The as-built locations of the sampling boreholes and trenches at Areas 1, 2 and 3 are shown in Figure 4.1.

4.76        On-site measurement including Photo-ionisation Detector (PID) measurement, free product and groundwater level measurement were undertaken in accordance with the approved CAP.  The elevated PID readings for soil samples are given in Appendix 4B.  In general, the VOC levels of the soil samples are low (i.e. below 10 ppm), which will not pose harmful effects to site workers during decontamination. The maximum PID reading of the soil samples is about 297.0 ppm (at additional borehole AB-39 (at 3.1-3.2m below ground)), which is considered localised.  Nevertheless, it is recommended that personal protective equipment (e.g. mask) be used the site workers for the decontamination works of that building.

4.77        Based on the results of the groundwater levels measurements, the groundwater level contours have been plotted in Figure 4.2.  It can be seen from Figure 4.2 that the predominant groundwater flow direction of the subject site is from hillside to the shore side.  The results of the groundwater level measurements are given in Appendix 4C.

Action Levels for Soil Remediation

4.78        The action levels for soil remediation are used to determine if remediation of soil is necessary.  In principle, the Dutch ‘ABC’ criteria are considered by the EPD as the remediation standards.  The Dutch ‘ABC’ criteria consist of 3 levels of standards, namely A, B, C, which generally indicate the followings:

·       ‘A’ level implies unpolluted;

·       ‘B’ level implies potential pollution present and requires further investigation or remediation; and

·       ‘C’ level implies pollution which requires remediation.

 

4.79        The action levels for soil remediation were used to determine if remediation of soil is necessary.  According to EPD’s requirements, these action levels are the Dutch ‘B’ Standards for the concerned chemicals.  For chemicals that are not included in the Dutch ‘B’ Standards, the USEPA federal standard’s Soil Screening Levels (SSLs) (published under Soil Screening Guidance : Technical Background Document) were used.  In this case, the SSLs for ingestion or inhalation, whichever is lower, were used.  If the chemicals are not included in the USEPA federal standard’s SSLs, then the USEPA Region IX PRGs were used to determine if soil remediation is necessary.

Action Level / Cleanup Target for Dioxins

4.80        The USEPA’s OSWER Directive 9200.4-26 (“Approach for Addressing Dioxin in Soil at Comprehensive Environmental Response, Compensation, and Liability Act (CERCLA) and Resource Conservation and Recovery Act (RCRA) Sites” signed 13 April 1998) states that 1 ppb TEQ is generally recommended as a cleanup target for dioxins for residential soils at CERCLA and RCRA sites (5 to 20 ppb TEQ has been selected for industrial use scenarios).  As such, 1 ppb TEQ is used as both the action level and cleanup target for dioxins in the present study.

Action Level for Tributyl-Tin (TBT) in Soil and Groundwater 

4.81        Tributyl-Tin (TBT) is a chemical commonly used as anti-fouling agent in paint coated on ships and therefore is a potential contaminant at shipyard sites.  TBT is a toxic to human beings and marine animals. 

4.82        The Dutch List does not include TBT in soil and groundwater.  However, the USEPA Region IX PRGs for TBT-oxide are 18 mg/kg and 260 mg/kg for residential soil and industrial soil respectively, and 11 mg/L for tap water.  Although the future land use of the study site is not residential and groundwater is not used for drinking purpose at the study site, for conservative approach, 18 mg/kg for residential soil and 11 mg/L for tap water are adopted as the cleanup criteria for soil and groundwater respectively. 

4.83        There are some reasons supporting the use of TBT-oxide standard for TBT.  Firstly, according to the Extension Toxicity Network maintained by University of California at Davis, Michigan State University, Cornell University, and Oregon State University, TBT by itself is unstable and will break down in the environment unless it is combined with an element such as oxygen.  One of the most common TBT compounds is bis (Tributyltin) Oxide (TBTO).  Therefore, it is considered that the TBT found at shipyards exist predominantly in the oxide form.

4.84        For the analysis of TBT in laboratory, the analysis method usually gives a result of total TBT, which includes the predominant TBTO and other possible forms of TBT.  As the TBT in soil is expected to be in the predominant form of TBTO.  Therefore, the use of TBT-oxide standard for TBT is justified.

4.85        As the analytical results for TBT in soil and groundwater are reported in mg Sn/ kg and mg Sn/L respectively, the RBC for TBT oxides are converted to equivalent concentration of tin for comparison with the analytical results.

4.86        Given the chemical formula of TBT-oxide as C24H54OSn2, 18 mg of TBT-oxide (the PRG for TBT-oxide) in 1 kg soil is equivalent to 7 mg/kg of Tin in soil.  Similarly, 11 mg of TBT oxide (the PRG for TBT-oxide) in 1 L groundwater is equivalent to 4.3 mg/L of Tin in groundwater.  Therefore, the action levels for TBT, in terms of Sn in soil and groundwater are 7 mg/kg of Sn (or 7,000 mg Sn/kg) in soil and 4.3 mg/L of Sn (4,300 hg Sn/L) in groundwater, respectively.

4.87        The action levels for soil remediation (including dioxins and TBT) are provided in Appendix 4A.

Screening Criteria for Groundwater

4.88        The Dutch ‘ABC’ criteria were established based on the assumption that groundwater is used as potable water.  However, as groundwater is not a source of potable water in Hong Kong, it is not practical to adopt the Dutch ‘B’ standards or the USEPA Region IX PRGs for tap water as the action levels for groundwater remediation in Hong Kong.  As such, a human risk assessment is used to derive the action level for groundwater contaminants that exceed the Dutch ‘B’ standards or the USEPA Region IX PRGs for tap water (if there is no Dutch ‘B’ standard for a certain chemical).  Therefore, the Dutch ‘B’ Standards or the USEPA Region IX PRGs for tap water are used for screening out the chemicals of concerns for risk assessment only.  All groundwater results with detectable concentrations were screened for risk assessment.  The Dutch ‘B’ standards were used as the first priority.  If there is no Dutch ‘B’ standards for a certain chemical, the USEPA Region IX PRGs were used.  The screening criteria for chemicals with detectable concentrations in groundwater samples are given in Appendix 4D.   

Nature of Contamination of Groundwater

4.89        The laboratory results of groundwater samples reveal some exceedances in the screening criteria, which are tabulated in Table 4.1.  The concerned test parameters include Antimony, Arsenic, Barium, Cadmium, Chromium, Cobalt, Copper, Lead, Molybdenum, Nickel, Zinc, Chloroform, Naphthalene, Bi(2-ethylhexyl)phathalate (DEHP) and Dioxins.

4.90        The laboratory results of TBT reveal that there are no exceedances in the screening criterion for TBT for all groundwater samples.  For all the 12 groundwater samples analysed for dioxins, only the groundwater sample collected from groundwater well AW-11 has non-zero dioxin TEQ of 2.76 x 10-7 mg/L (please refer Table 4.1).  The source of the dioxins in that groundwater sample is considered to be the historical burning activities took place in the burn pit locating adjacent to and up-gradient of the groundwater well.  As dioxins are very insoluble in water and dioxins have a strong tendency to sorb to fine soil particles, the likelihood of wide spread solubilisation of dioxins is considered very low.  It is likely that the dioxins detected in that sample were related to colloidal or finely suspended particles within the groundwater sample because the groundwater samples were not filtered in the field.  Furthermore, as there were no other organic contaminants detected in that sample and no other wells adjacent to or up-gradient of that well exhibit non-zero dioxin TEQ, the source of the dioxins is considered localised and the groundwater impacts are insignificant.  Nevertheless, this dioxin laboratory result will be assessed in the risk assessment.

Table 4.1      Groundwater Results with Exceedances in Screening Criteria

Groundwater Sample

Contaminant

Unit (mg/L or otherwise specified)

Concentration

MW-B24

Chromium

mg/L

67

MW-B24

Copper

mg/L

58

MW-B24

Nickel

mg/L

7200

MW-B24

TPH

mg/L

231

MW-B24

Zinc

mg/L

250

MW-B34

Barium

mg/L

261

MW-B34

Naphthalene

mg/L

25

MW-C2

Barium

mg/L

108

MW-D6

Barium

mg/L

130

MW-D6

TPH

mg/L

433

MW-J7

Barium

mg/L

106

MW-L34

Cadmium

mg/L

4.3

MW-L34

TPH

mg/L

304

MW-L37

Cadmium

mg/L

5.5

MW-OB5

Barium

mg/L

240

MW-OB11

Bis(2-ethylhexyl)phthalate

mg/L

27

MW-OB11

TPH

mg/L

449

MW-P8

Cadmium

mg/L

7.7

MW-P8

TPH

mg/L

459

MW-Q1

Zinc

mg/L

742

MW-Q5

Zinc

mg/L

620

MW-S4

Zinc

mg/L

788

MW-S8

Molybdenum

mg/L

29

GW-T19(5-6)

Arsenic

mg/L

38

GW-T19(5-6)

Barium

mg/L

134

GW-T20(7-8)

Barium

mg/L

354

GW-T22(1-2)

Barium

mg/L

181

GW-T22(1-2)

Molybdenum

mg/L

42

GW-T22(3-4)

Antimony

mg/L

44

GW-T22(3-4)

Barium

mg/L

669

GW-T22(3-4)

Cadmium

mg/L

3.1

GW-T22(3-4)

Copper

mg/L

1187

GW-T22(3-4)

Lead

mg/L

725

GW-T22(3-4)

Molybdenum

mg/L

50

GW-T22(3-4)

Nickel

mg/L

77

GW-T22(3-4)

Zinc

mg/L

1200

GW-T26(1-2)

Arsenic

mg/L

37

GW-T26(1-2)

Barium

mg/L

747

GW-T26(1-2)

Cadmium

mg/L

17.8

GW-T26(1-2)

Cobalt

mg/L

166

GW-T26(1-2)

Copper

mg/L

259

GW-T26(1-2)

Lead

mg/L

2254

GW-T26(1-2)

Zinc

mg/L

519

GW-T29(3-4)

Barium

mg/L

120

AW-1C

Chloroform

mg/L

0.7

AW-2

Barium

mg/L

146

AW-2

Zinc

mg/L

237

AW-5

Zinc

mg/L

206

AW-10

TPH

mg/L

213

AW-12

Barium

mg/L

233

AW-13

Molybdenum

mg/L

28

AW-14

Barium

mg/L

220

AW-15

Molybdenum

mg/L

23

AW-16a

Barium

mg/L

101

AW-11

Dioxins

mg/L

2.76 x 10-7 (TEQ)

         Remark:

Groundwater samples with suffix “MW” are groundwater samples collected from originally proposed groundwater wells; groundwater samples with suffix “GW” are groundwater samples collected from trenches; groundwater samples with suffix “AW” are groundwater samples collected from additional groundwater wells.

 

4.91        The evaluation of significance of risk due to groundwater contamination is shown in Table 4.2.  It can be seen from Table 4.2 that the risk due to ingestion of groundwater by site workers is warranted.  It should be noted that the risk due to dermal contact with groundwater by site workers is uncertain.  It is because risk assessment regarding to dermal contact cannot be undertaken as the toxicity and/or chemical specific data for the chemicals of concern (COCs) do not exist.  As such, it is recommended that personal protective equipment be used by site works as a mitigation measure.   

 

Table 4.2      Evaluation of Significance of Risk Due to Groundwater Contamination

Nature of Receptor

Specific Receptor

Significance of Risk due to Groundwater Contamination

Rationale

Terrestrial Ecology

Trees

 Insignificant

As the existing groundwater level is about 2m below ground and the site will be covered by filling materials of about 3m thick, roots of trees will not reach the groundwater which is at 5m below ground.

Marine Ecology

Marine species in off-site surface watercourse

 Insignificant

The level of any contaminant in surface watercourse will be very low due to the dilution effect when groundwater seeps into surface watercourse.

Artificial lake of planned Water Recreation Centre

 Insignificant

Please to Chapter 7 “Water Quality” for the assessment of potential impact of the groundwater quality on the artificial lake of the planned Water Recreation Centre.

Humans

 

Construction workers (by ingestion)

 Significant

Existence of potential risk. 

Construction workers (by inhalation)

 Insignificant

The levels of volatile contaminants in groundwater are very low because the levels of VOCs in groundwater are below the screening criteria. 

Construction workers (by dermal contact)

 Uncertain

Toxicity and/or chemical specific data do not exist for the chemicals of concern (COCs) for risk assessment to be undertaken.  As such, it is recommended that personal protective equipment be used by site works as a mitigation measure.

Future land users

 Insignificant

Groundwater at the site will not be used as potable water or used for recreation/irrigation purposes.

Personnel for maintenance in future

 Insignificant

Existing groundwater level is about 3m below ground and the site will be covered by filling materials of about 37-8m thick.  Level of utility will be limited to 1-2 m below ground.   

 

4.92        The risk assessment was based on the scenario of exposure of human receptors to contaminated groundwater in future.  The analysed concentrations of various parameters in groundwater, the anticipated most sensitive human receptor and the potential exposure pathways were taken into account in the risk assessment.

4.93        For each parameter, the source concentration is the maximum concentration of that parameter found in the groundwater samples irrespective of their locations.  Chromium was assumed to be Cr(VI) for conservative assessment.  The maximum source concentration (of groundwater samples) of the chemicals of concern (i.e. with concentration above the screening criteria or with detectable concentration for dioxins) and their corresponding noncarcinogenic oral reference doses or carcinogenic slope factor are tabulated in Table 4.3.  It should be noted that for lead, World Health Organisation’s (WHO) oral reference dose (3.6 x 10-3 mg/kg-day) was adopted for the risk assessment.

 

Table 4.3      Maximum Source Concentrations and Noncarcinogenic Oral Reference Doses/Carcinogenic Oral Slope Factors of Chemicals of Concern

Parameter

Max. Source Concentration (of groundwater samples) (mg/L)

Sample I.D.

Noncarcinogenic Oral Reference Doseb (RfDo) (mg/kg-day)

Min. Noncarcinogenic Oral Reference Doseb (RfDo) (mg/kg-day)

Carcinogenic Oral Slope Factorc (CSFo) 1/(mg/kg-day)

Antimony

4.40E-02

GW-T22(3-4)

4.00E-04

Not applicable

Not applicable

Arsenic

3.80E-02

GW-T19(5-6)

3.00E-04

Not applicable

1.50E+00

Barium

7.47E-01

GW-T26(1-2)

7.00E-02

Not applicable

Not applicable

Bis(2-ethylhexyl)phthalate (DEHP)

2.70E-02

MW-OB11

2.00E-02

Not applicable

1.40E-02

Cadmium

1.78E-02

GW-T26(1-2)

5.00E-04

Not applicable

Not applicable

Chloroform

7.00E-04

AW-1C

1.00E-02

Not applicable

6.10E-03

Chromium (VI)a

6.70E-02

MW-B24

3.00E-03

Not applicable

7.30E-03

Cobalt

1.66E-01

GW-T26(1-2)

6.00E-02

Not applicable

Not applicable

Copper

1.19E+00

GW-T22(3-4)

3.70E-02

Not applicable

Not applicable

Lead

2.25E+00

GW-T26(1-2)

3.60E-03

Not applicable

Not applicable

Molybdenum

5.00E-02

GW-T22(3-4)

5.00E-03

Not applicable

Not applicable

Naphthalene

2.50E-02

MW-B34

2.00E-02

Not applicable

Not applicable

Nickel

7.20E+00

MW-B24

2.00E-02

Not applicable

Not applicable

TPHs

4.59E-01

MW-P8

3.00E-02 to 5.00E+00

3.00E-02

Not applicable

Zinc

1.20E+00

GW-T22(3-4)

3.00E-01

Not applicable

Not applicable

Dioxins

2.76E-07

AW-11

Not applicable

Not applicable

1.50E+05

a    Chromium is assumed to be Cr (VI) for conservative assessment.

b    Source for TPHs : Total Petroleum Hydrocarbons Criteria Working Group (1999).  Total Petroleum Hydrocarbons Criteria Working Group Series Volume 5 – Human Health Risk-Based Evaluation of Petroleum Release Sites: Implementing the Working Group Approach.  Massachusetts, U.S.A., Amherst Scientific Publishers.

      Source for Antimony (Sb), Arsenic (As), Ba, DEHP, Cd, Chloroform, Cr(VI), Co, Cu, Pb, Mo, Naphthalene, Ni and Zn : USEPA Region IX Risk-based Concentration Table (revised on 1 Nov 2000), USEPA Region IX.

Source for Lead : World Health Organisation.   

c     Source for Arsenic (As), DEHP, Chloroform and Dioxins : USEPA Region IX Risk-based Concentration Table (revised on 1 Nov 2000), USEPA Region IX.

Source for Cr(VI ):  USEPA Region III Risk-based Concentration Table, USEPA Region III, March 7, 1995.

 

4.94        The details of the risk assessment for groundwater are given in Appendix 4E.  According to the results of the risk assessment, the concentrations of all chemicals of concern do not exceed the calculated ‘allowable’ concentrations.  As the “allowable” concentration for TPH derived from the risk assessment (2.13E+02 mg/L) is above the solubility limit of TPH in water, the remediation criterion for TPH is considered as “no free product” present in groundwater.  As the clay content of backfilled clean soil would be very low, the distribution coefficients for the metals in groundwater adsorbing onto the backfilled clean soil would also be very low.  As such, it is unlikely that the metals in groundwater will re-contaminate backfilled clean soil.  The derived ‘allowable’ concentrations for the chemicals of concern for groundwater are tabulated in Table 4.4.

Table 4.4      Derived ‘Allowable’ Concentrations for Chemicals of Concern for Groundwater

Parameter

Calculated ‘Allowable’ Concentrations (mg/L)

Antimony

2.84E+00

Arsenic

3.31E-01

Barium

4.97E+02

Bis(2-ethylhexyl)phthalate (DEHP)

3.55E+01

Cadmium (Cd)

3.55E+00

Chloroform

7.10E+01

Chromium (VI)

2.13E+01

Cobalt

4.26E+02

Copper

2.63E+02

Lead

2.56E+01

Molybdenum

3.55E+01

Naphthalene

1.42E+02

Nickel

1.42E+02

TPH

No free producta

Zinc

2.13E+03

Dioxins

3.31E-06

a    Indicates that the derived remediation target is above the solubility limit of the contaminant, i.e. the concentration of the contaminant in water will not exceed the derived remediation target.

 

4.95        The results of the risk assessment indicate that the concentrations of the chemicals of concern of the groundwater samples do not exceed the ‘allowable’ concentrations.  Therefore, remediation of groundwater is considered not necessary.  This consideration is supported by the followings:

i)      there will be no beneficial use of groundwater at the CLS site during both construction and operation stages (please also refer Section 4.88);

 

ii)    during construction, any groundwater pumped out at the CLS site will be recharged back to the ground at the same site (please also refer Section 4.97 and Section 7.48);

 

iii)   the water level in the artificial lake will be at a higher level than the contaminated groundwater and will be lined with a impermeable liner, hence the artificial lake will not be affected (please also refer Section 7.50);

 

iv)   the contaminated soil at the CLS site will be excavated for on-site or off-site treatment during the project construction stage (please also refer Sections 4.158 and 4.159). 

 

Nevertheless, as the risk due to dermal contact by site workers is uncertain, it is recommended that personal protective equipment be used by site works as a mitigation measure.

4.96        Floating oil/free product (of TPH) has only been found in Building D, with maximum thickness being several inches.  As the free product is very localised, it appears that the quantity of the free product would be small (i.e. less than 100 litres).  As such, it is proposed that where free product is detected at the groundwater surface at excavated areas within Building D, only the free product shall be skimmed off manually.  The skimmed free product shall be then be drummed properly and collected by a licensed chemical waste collector for disposal.  Skimming of free product shall continue until no free product can be measured by an interface probe (with usual detection limit of about 1.5mm).  At that time, a confirmation sample of groundwater shall be collected at the surface of the excavated area and analysed for TPH by a laboratory accredited by the Hong Kong Laboratory Accreditation Scheme (HOKLAS).  If the TPH concentration of the groundwater sample is below the “allowable” TPH concentration derived from the risk assessment (2.13E+02 mg/L, please refer to Section 4.95 above), the removal of all TPH free product is considered completed.  Failing this, skimming of free product shall continue and additional confirmation sample shall be collected there is no exceedance in the “allowable” until there is no exceedance in the “allowable” TPH concentration.     

4.97        Discharge to surface watercourse will not be carried out.  Where dewatering is necessary during excavation, the groundwater at the excavated area water at excavation will be recharged on-site within the 10m-zone around from the boundary of the excavated area.  The water shall be recharged in continuous mode.  The physical test results for the soil samples taken at the groundwater well locations across the CLS site (Appendix 4F) indicate that the soil beneath the site is predominately sand with relatively high hydraulic conductivity.  Owing to the short distance between the excavation area and the recharge point, and the high hydraulic conductivity of sandy soil, the groundwater at the recharge location will be driven to flow away from the recharge point and towards the excavated area.

4.98        In order to detect if there is any likelihood of migration of contaminants in soil due to locally risen groundwater level during recharge, it is recommended to install 5 groundwater monitoring wells: one at the recharge point and four 5m apart from the recharge point in four directions.  Figure 4.3 depicts a typical extraction point, recharge point and the groundwater monitoring locations.  The baseline groundwater level at the 5 monitoring wells shall be measured before any recharge.  During the recharge period, the groundwater level at the 5 monitoring wells shall be monitored regularly (every 5 minutes in the first hour, hourly check afterwards) to check that the groundwater at the recharge point flows toward the excavated area and there is no likelihood of migration of contaminants in soil due to locally risen groundwater level during recharge.  The details of the monitoring requirements are provided in Chapter 5 of “Environmental Monitoring and Audit Manual”. 

Nature of Contamination of Soil Samples

4.99        Generally, the laboratory results reveal that the major contaminants in soils are metals (mainly barium, copper, lead and zinc) and total petroleum hydrocarbons (TPH).  Semivolatile organic compounds (SVOCs) and dioxins are also found in some soil samples.

Area 1

4.100     The major sources of the contamination in Area 1 are associated with the historical operations undertaken within and outside the buildings.  Chemicals with exceedance in the relevant standards were found in some buildings including Buildings B, D, I, J, L, M, N, O and P.  The most significant soil contamination occurs in Building B (metals and TPHs), Building D (TPHs, metals and SVOCs), and Building L (metals and TPHs).  Soils contaminated with metals (i.e. with levels higher than the relevant standards) are also found in boreholes advanced amongst the buildings.

4.101     Some additional boreholes were drilled in the roads and between buildings to further assess the soil contamination.

Building A

4.102     A total of 15 soil samples were collected from 3 boreholes inside the building to access the overall contamination in the vicinity of the building.  No exceedance in the relevant standards was found.

Building B

4.103     A total of 141 soil samples from 34 boreholes and 2 ground water samples were collected at this building to assess the overall contamination in the vicinity of the building.  The exceedances in the relevant standards are summarised in Table 4.5.

 

 

Table 4.5      Analytical Results for Soil Samples of Building B

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-B2

0.15-0.30

Copper

103

B-B4

0.12-0.27

Nickel

275

B-B4

0.68-0.83

Nickel

289

B-B8

0.15-0.30

Chromium

508

B-B8

0.15-0.30

Nickel

152

B-B14

0.68-0.77

Nickel

161

B-B18

0.11-0.16

Chromium

906

B-B20

0.11-0.26

Copper

130

B-B20

0.11-0.26

Nickel

153

B-B21

0.12-0.29

Nickel

404

B-B21

0.65-0.81

Nickel

148

B-B21

1.45-1.61

Nickel

215

B-B22

0.14-0.29

Copper

234

B-B22

0.14-0.29

Nickel

444

B-B22

0.68-0.83

Copper

541

B-B22

0.68-0.83

Nickel

196

B-B22

1.38-1.68

Copper

167

B-B22

1.38-1.68

Nickel

148

B-B23

0.13-0.29

Chromium

2670

B-B23

0.13-0.29

Copper

331

B-B23

0.13-0.29

Lead

153

B-B23

0.65-0.81

Copper

775

B-B23

0.65-0.81

Nickel

380

B-B23

1.40-1.56

Copper

354

B-B23

1.40-1.56

Nickel

397

B-B23a

2.85-3.10

Copper

109

B-B23a

2.85-3.10

Nickel

297

B-B24

0.14-0.29

Copper

122

B-B24

0.14-0.29

Nickel

195

B-B24

0.68-0.83

Chromium

575

B-B24

0.68-0.83

Copper

1790

B-B24

0.68-0.83

Cyanide

123

B-B24

0.68-0.83

Nickel

1780

B-B24

2.88-3.13

Nickel

212

B-B25

0.15-3.0

Chromium

291

B-B25

0.15-3.0

Nickel

298

B-B25

0.68-0.83

Chromium

417

B-B25

1.38-1.63

Nickel

119

B-B25

2.88-3.13

Chromium

700

B-B25

2.88-3.13

Nickel

174

B-B26

0.13-0.29

Nickel

210

B-B26

0.65-0.81

Nickel

206

B-B27

0.13-0.28

Nickel

110

B-B27

0.45-0.69

Nickel

195

B-B33

0.08-0.23

TPH

1343

B-B33

0.08-0.23

Copper

274

B-B34

0.07-0.22

TPH

1868

 

Building C

4.104     A total of 22 soil samples and 1 groundwater sample were collected at 4 boreholes to assess the overall contamination in the vicinity of the building.  No exceedance in the relevant standards was found.

Building D

4.105     Twenty-four (24) boreholes were drilled and 1 monitoring well was installed in the vicinity area of the building.  A total of 109 soil samples and 1 groundwater sample were collected to assess the overall contamination in the vicinity of the building.  The exceedances in the relevant standards are highlighted in Table 4.6.

Table 4.6      Analytical Results for Soil Samples of Building D

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-D1

2.24-2.51

TPH

1495

B-D4

0.63-0.79

TPH

1947

B-D4

1.45-1.61

TPH

25891

B-D4

1.45-1.61

Naphthalene

20

B-D5

1.47-1.63

TPH

16563

B-D5

1.47-1.63

Naphthalene

10.9

B-D6

0.63-0.88

TPH

15989

B-D6

0.63-0.88

Naphthalene

11.4

B-D6

1.37-1.62

TPH

8417

B-D6

1.37-1.62

Naphthalene

14.1

B-D7

1.47-1.63

TPH

3204

B-D8

0.15-0.31

TPH

12283

B-D8

0.64-0.80

TPH

14973

B-D8

0.64-0.80

Zinc

550

B-D8

1.46-1.62

TPH

13030

B-D15

1.38-1.63

Copper

191

B-D18

0.05-0.20

Copper

783

B-D18

0.05-0.20

Lead

205

B-D18

0.05-0.20

Zinc

574

B-D19

0.02-0.17

Copper

1100

B-D19

0.02-0.17

Zinc

968

B-D21

0.14-0.29

Chromium

300

B-D23

0.07-0.22

Copper

1400

B-D23

0.07-0.22

Zinc

800

B-D25

1.40-1.65

TPH

25218

B-D25

1.40-1.65

Naphthalene

20.8

B-D26

1.40-1.65

TPH

9548

B-D26

1.40-1.65

Naphthalene

8

 

Building H

4.106     Ten (10) boreholes were drilled within the building and the vicinity area.  A total of 15 soil samples was collected.  No exceedance was found.

Building I

4.107     A total of 40 soil samples and 1 groundwater sample were collected from 12 boreholes to assess the overall contamination in the building.  Exceedances were found at the samples collected.  The exceedances are highlighted in Table 4.7.

 

Table 4.7      Analytical Results for Soil Samples of Building I

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-I1

1.40-1.55

Copper

507

B-I2

0.10-0.26

TPH

1214

B-I5

0.12-0.28

Copper

578

B-I7

0.1-0.25

Lead

181

 

Building J

4.108     A total of 30 soil samples and 1 groundwater sample were collected from 7 borehole locations to assess the overall contamination in the building and the vicinity area.  The exceedances are tabulated in Table 4.8.

Table 4.8      Analytical Results for Soil Samples of Building J

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-J4

1.02-1.27

Lead

494

B-J6

0.0-0.16

Copper

899

B-J6

0.0-0.16

Lead

777

B-J6

0.0-0.16

Nickel

140

B-J6

0.0-0.16

Zinc

974

 

Building K

4.109     A total of 25 soil samples were collected from 5 borehole locations to assess the overall contamination in the building.  No exceedance in the relevant standards was found.

Building L

4.110     Thirty-eight (38) boreholes were drilled and 3 of them were installed as monitoring wells in the vicinity area of the building.  The exceedances are highlighted in Table 4.9.

Table 4.9      Analytical Results for Soil Samples of Building L

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-L1

0.68-0.83

Lead

165

B-L2

0.20-0.35

TPH

6325

B-L2

0.20-0.35

Copper

210

B-L2

0.35-1.00

TPH

5819

B-L2

1.40-1.65

TPH

21814

B-L3

0.15-0.30

TPH

3092

B-L7

0.08-0.23

TPH

12220

B-L7

0.83-0.98

TPH

1056

B-L13

0.0-0.16

Copper

1850

B-L13

0.0-0.16

Nickel

110

B-L13

0.0-0.16

Zinc

545

B-L15

0.0-0.16

Copper

430

B-L15

0.0-0.16

Zinc

636

B-L16

0.0-0.16

Copper

283

B-L16

0.0-0.16

Copper

102

B-L16

0.0-0.16

Lead

170

B-L17

0.0-0.16

Copper

485

B-L17

0.63-0.79

Copper

111

B-L19

0.10-0.26

Copper

350

B-L20

0.0-0.16

Copper

845

B-L20

0.0-0.16

Lead

535

B-L20

0.0-0.16

Zinc

1590

B-L22

0.10-0.26

TPH

4201

B-L23

0.0-0.16

Copper

564

B-L23

0.0-0.16

Lead

267

B-L23

0.0-0.16

Nickel

138

B-L23

0.0-0.16

Zinc

562

B-L24

0.0-.016

Cadmium

18.1

B-L24

0.0-.016

Cobalt

52.4

B-L24

0.0-.016

Copper

2680

B-L24

0.0-.016

Lead

1740

B-L24

0.0-.016

Nickel

1140

B-L24

0.0-.016

Zinc

4180

B-L25

0.0-0.13

Cadmium

10.7

B-L25

0.0-0.13

Cobalt

70.3

B-L25

0.0-0.13

Copper

876

B-L25

0.0-0.13

Lead

447

B-L25

0.0-0.13

Nickel

1260

B-L25

0.0-0.13

Zinc

2940

B-L26

0.0-0.16

Antimony

66.59

B-L26

0.0-0.16

Cadmium

6.92

B-L26

0.0-0.16

Copper

235

B-L26

0.0-0.16

Lead

26300

B-L26

0.68-0.84

Copper

237

B-L26

0.68-0.84

Lead

521

B-L26a

1.40-1.65

Lead

368

B-L28

0.10-0.26

Arsenic

31.6

B-L28

0.10-0.26

Copper

377

B-L28

0.10-0.26

Lead

420

B-L28

0.10-0.26

Nickel

143

B-L28

0.64-0.80

Chromium

624

B-L29

0.15-0.31

TPH

1267

B-L29

0.15-0.31

Chromium

429

B-L30

0.0-0.16

Copper

281

B-L30

0.0-0.16

Lead

880

B-L30

0.0-0.16

Nickel

349

B-L31

0.0-0.16

Barium

494

B-L31

0.0-0.16

Copper

1380

B-L31

0.0-0.16

Lead

1060

B-L31

0.0-0.16

Nickel

125

B-L31

0.0-0.16

Zinc

1510

B-L32

0.0-0.16

Copper

499

B-L33

0.0-0.16

TPH

2376

B-L33

0.0-0.16

Copper

1180

B-L33

0.0-0.16

Lead

488

B-L33

0.0-0.16

Zinc

812

 

Building M

4.111     Eight (8) boreholes were drilled and 1 monitoring well was installed within the building.  A total of 28 soil samples and 1 groundwater sample were collected.  The exceedances are shown in Table 4.10.

Table 4.10     Analytical Results for Soil Samples of Building M

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-M1

0.10-0.25

Arsenic

30.5

B-M1

0.10-0.25

Chromium

303

B-M1

0.10-0.25

Copper

127

B-M1

0.10-0.25

Nickel

867

B-M1

0.68-0.87

Chromium

331

B-M1

0.68-0.87

Nickel

322

B-M5

0.07-0.22

Nickel

302

B-M6

0.0-0.16

Copper

4490

B-M6

0.0-0.16

Lead

1390

B-M6

0.0-0.16

Dioxins

6.070 ppb (TEQ)

B-M6

0.65-0.81

Copper

579

B-M6

0.65-0.81

Lead

448

B-M6

0.65-0.81

Nickel

327

 

Building N

4.112     A total of 26 soil samples and 1 groundwater sample were collected to assess overall contamination of the building.  The exceedance in the relevant standards are summarised in Table 4.11.

Table 4.11     Analytical Results for Soil Samples of Building N

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-N1

0.02-0.18

TPH

2696

B-N1

1.43-1.59

TPH

1917

B-N2

0.07-0.22

Cadmium

5.28

B-N2

0.07-0.22

TPH

8615

B-N2

0.07-0.22

Copper

504

B-N2

0.07-0.22

Lead

245

B-N2

0.07-0.22

Nickel

178

B-N2

0.07-0.22

Tin

139

B-N5

0.68-0.83

Copper

255

B-N6

0.05-0.20

Lead

249

B-N6

1.40-1.65

TPH

1644

 

Building O

4.113     A total of 51 soil samples and 1 groundwater sample were collected from 10 borehole locations to assess the overall contamination.  The exceedances are tabulated in Table 4.12.

Table 4.12     Analytical Results for Soil Samples of Building O

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-O2

0.78-1.03

Lead

191

B-O6

1.63-1.73

Copper

290

B-O7

0.15-0.30

Copper

1260

 

Building P

4.114     Ten (10) boreholes were drilled and 1 monitoring well were installed in the building.  A total of 38 soil samples and 1 groundwater sample were collected.  The exceedances are summarised in Table 4.13.

Table 4.13     Analytical Results for Soil Samples of Building P

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-P1

0.10-0.26

Lead

475

B-P6

0.40-0.56

TPH

13645

B-P10

0.08-0.23

TPH

19239

B-P10

0.68-0.83

TPH

5881

 

Outside Boring Boreholes in Area 1 (OB)

4.115     Ten (10) boreholes were drilled and 4 monitoring wells were installed in Area 1.  A total of 48 soil samples and 4 groundwater samples were collected to assess the area of outside building in Area 1.  The exceedances are summarised in Table 4.14.

Table 4.14     Analytical Results for Soil Samples for Outside Borings in Area 1

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

OB-5

0.15-0.25

Barium

1100

OB-5

0.15-0.25

Chromium

274

OB-5

0.15-0.25

Copper

2780

OB-5

0.15-0.25

Lead

2730

OB-5

0.15-0.25

Nickel

221

OB-5

0.15-0.25

Zinc

1740

OB-5

1.40-1.65

Copper

713

OB-5

1.40-1.65

Lead

1830

OB-5

2.87-3.12

Copper

150

OB-5

2.87-3.12

Lead

502

 

Surface Drainage Boreholes in Area 1 (SD)

4.116     Twelve (12) boreholes were drilled to verify the overall contamination around surface drainage.  The exceedances in the relevant standards are highlighted in Table 4.15.

Table 4.15     Analytical Results for Soil Samples of Surface Drainage Borings in Area 1

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

SD-1

0.08-0.23

TPH

1198

SD-3

0.15-0.30

Copper

380

SD-4

0.08-0.23

Copper

291

SD-6

0.07-0.22

Copper

117

SD-7

0.08-0.23

Copper

1280

SD-8

0.0-0.18

Copper

130

SD-9

0.0-0.18

Lead

230

 

Trenches for Debris Pile

4.117     Eleven (11) trenches with total length of approximately 215m for debris pile were excavated, with total number of soil samples being 45.  It should be noted that only one of these trenches was excavated in Area 1.  The exceedances are tabulated in Table 4.16.

Table 4.16     Analytical Results for Soil Samples of Debris Pile in Area 1

Trench Number

Depth (m)

Sample ID

Contaminant

Concentration (mg/kg or otherwise specified)

T1

0.74

T1/0.74m/2

Copper

105

T1

0.74

T1/0.74m/2

Lead

311

 

Additional Boreholes in Area 1

4.118     Thirty-nine (39) additional boreholes have been drilled in Area 1 to delineate the soil contamination extent in Area 1 more exactly.  The exceedances in the relevant standards are tabulated in Table 4.17.

 

Table 4.17     Analytical Results for Soil Samples of Additional Boreholes in Area 1

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or  otherwise specified)

AB-1

0.08-0.23

TPH

5942

AB-3

0.08-0.23

TPH

1206

AB-14

0.05-0.30

Chromium

682

AB-14

0.05-0.30

Hexavalent Chromium

392

AB-14

0.68-0.83

Chromium

788

AB-14

0.68-0.83

Hexavalent Chromium

288

AB-15

0.78-0.93

Arsenic

54.4

AB-15

0.78-0.93

Barium

848

AB-15

0.78-0.93

Chromium

841

AB-15

0.78-0.93

Copper

4960

AB-15

0.78-0.93

Lead

1260

AB-15

0.78-0.93

Nickel

228

AB-15

0.78-0.93

Zinc

2380

AB-21

0.45-0.56

TPH

2802

AB-22

0.70-0.85

Lead

157

AB-25

0.08-0.23

Copper

7680

AB-25

0.08-0.23

Zinc

9090

AB-34

0.08-023

Chromium

280

AB-38

1.35-1.60

TPH

13965

 

4.119     The maximum and average concentrations of contaminants in Area 1 with exceedance in the relevant standards are given in Table 4.18.

Table 4.18     Maximum and Average Concentrations of Contaminants in Area 1 with Exceedance

 

 

Unit

No. of Exceedance

No. of Samples Analysed

Maximum

Average (exceedance only)

Overall Average

Antimony

Mg/kg

1

780

67

67

0.203

Arsenic

Mg/kg

3

778

54

39

1.222

Barium

Mg/kg

3

779

1100

814

29.474

Cadmium

Mg/kg

4

779

18

10

0.142

TPH

Mg/kg

36

862

25891

8053

364.577

Chromium

Mg/kg

17

778

2670

642

23.135

Cobalt

Mg/kg

2

779

70

61

2.411

Copper

Mg/kg

56

778

7680

883

71.677

Cyanide

Mg/kg

1

701

123

123

0.211

Hexavalent Chromium

Mg/kg

2

687

392

340

1.579

Lead

Mg/kg

32

775

26300

1417

81.677

Naphthalene

Mg/kg

6

747

20.80

14.20

0.128

Nickel

Mg/kg

39

777

1780

334

21.350

Tin

Mg/kg

1

778

139

139

0.628

Zinc

Mg/kg

16

778

9090

1866

76.376

Dioxins

Ppb (TEQ)

1

11

6.070

6.070

0.581

 

Area 2

4.120     The soil contamination found in Area 2 appears to be associated with the historical operations in the buildings within this area, areas adjacent to several buildings, and in the waste disposal mounds and pits located east to Buildings of S and T.  Major soil contamination occurs in Building S (metals, TPHs and SVOCs) and Building T (metals, SVOCs and TPHs), debris pile area (metals, TPHs and SVOCs) and burn pit area (metals and dioxins).

Building R

4.121     Four boreholes were drilled and one of them was installed as monitoring well.  A total of 22 soil samples and 1 groundwater sample were collected to assess the overall contamination of the building.  The only exceedance in the relevant standards is shown in Table 4.19.

Table 4.19     Analytical Results for Soil Samples of Building R

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-R3

0.71-0.86

Lead

155

 

Building S

4.122     A total of 50 soil samples and 2 groundwater samples were collected.  They come from 12 borehole locations and 2 of them were then installed with groundwater monitoring wells.  The exceedances are tabulated in Table 4.20.

Table 4.20     Analytical Results for Soil Samples of Building S

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-S6

0.18-0.34

Copper

159

B-S8

0.08-0.23

TPH

11219

B-S9

0.30-0.45

Benzo(a)anthracene

1.18

B-S9

0.30-0.45

Benzo(b)fluoranthene

1.26

B-S9

0.30-0.45

TPH

1362

B-S9

0.30-0.45

Dibenz(a,h)anthracene

0.16

B-S10

0.17-0.32

Lead

431

B-S11

0.68-0.82

Copper

126

 

Building T

4.123     Twelve (12) boreholes were drilled and two (2) of them were installed as monitoring wells in the area vicinity to the building.  A total of 58 soil samples and two groundwater samples were collected.  The exceedances are highlighted in Table 4.21.

Table 4.21     Analytical Results for Soil Samples of Building T

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-T3

0.12-0.30

Barium

789

B-T5

0.35-0.53

Barium

437

B-T5

0.35-0.53

Benzo(a)anthracene

1.22

B-T5

0.35-0.53

Benzo(b)fluoranthene

1.15

B-T5

0.35-0.53

Copper

2950

B-T5

0.35-0.53

Dibenz(a,h)anthracene

0.159

B-T5

0.35-0.53

Lead

1760

B-T5

0.35-0.53

Zinc

1300

B-T5

1.28-1.72

Copper

156

B-T6

0.25-0.40

TPH

7635

B-T6

0.68-0.83

TPH

1289

 

Additional Boreholes in vicinity of Building T

4.124     Twenty-two (22) additional boreholes have been drilled inside or in the vicinity of Building T to delineate the soil contamination extent near this building more exactly.  The exceedances in the relevant standards are tabulated in Table 4.22.

Table 4.22     Analytical Results for Soil Samples of Additional Boreholes near Building T 

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

AB-T3

0.08-0.23

Benzo(a)anthracene

1.6

AB-T3

0.08-0.23

Benzo(a)pyrene

1.43

AB-T3

0.08-0.23

Benzo(b)fluoranthene

1.4

AB-T3

0.08-0.23

Dibenz(a,h)anthracene

0.212

AB-T3

0.08-0.23

Indeno(1,2,3-cd)pyrene

1.09

AB-T6

0.10-0.25

Copper

245

AB-T6

0.65-0.80

Copper

208

AB-T7

0.30-0.45

Bis(2-ethylhexyl)phthalate

46

AB-T8

0.25-0.40

Copper

179

AB-T12

0.40-0.56

TPH

2558

AB-T15

0.65-0.80

Lead

155

AB-T18

0.35-0.50

Copper

362

AB-T21a

0.08-0.23

Copper

398

AB-T22

0.20-0.35

Copper

110

AB-T22

0.20-0.35

Copper

110

 

Building U

4.125     A total of 11 soil samples and 1 groundwater sample were collected to assess the overall contamination of the building and the vicinity.  No exceedance in the relevant standards was found.

Building V

4.126     A total of 47 soil samples and 1 groundwater sample were collected to assess the overall contamination of the building.  The exceedances are summarised in Table 4.23.

Table 4.23     Analytical Results for Soil Samples of Building V

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-V2

0.68-0.83

TPH

3120

B-V2

0.68-0.83

Copper

166

 

Building W

4.127     A total of 24 soil samples were collected from 6 boring locations.  The exceedances are tabulated in Table 4.24.

Table 4.24     Analytical Results for Soil Samples of Building W

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-W2

0.20-0.35

TPH

7648

B-W2

0.20-0.35

Lead

414

 

Building X

4.128     Five boreholes were drilled and one of them was installed as a monitoring well.  A total of 19 soil samples and 1 groundwater sample were collected.  The only exceedance is shown in Table 4.25.

Table 4.25     Analytical Results for Soil Samples of Building X

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-X4

0.11-0.26

Dibenz(a,h)anthracene

0.093

 

Building Y

4.129     A total of 25 soil samples were collected to assess the overall contamination of the building.  The exceedances are summarised in Table 4.26.

Table 4.26     Analytical Results for Soil Samples of Building Y

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-Y4

0.08-0.23

Benzo(a)anthracene

1.67

B-Y4

0.08-0.23

Benzo(a)pyrene

1.6

B-Y4

0.08-0.23

Benzo(b)fluoranthene

1.5

B-Y4

0.08-0.23

Dibenz(a,h)anthracene

0.18

B-Y4

0.08-0.23

Indeno(1,2,3-cd)pyrene

0.92

 

Building Z

4.130     A total of 29 soil samples were collected from 6 boring locations.  One of them was installed as monitoring well and a groundwater sample was taken.  The exceedances are tabulated in Table 4.27.

Table 4.27     Analytical Results for Soil Samples of Building Z

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-Z2

0.25-0.40

TPH

7032

 

Outside Borings in Area 2 (OB)

4.131     Twenty-one (21) boreholes were drilled and six (6) of them were installed as groundwater monitoring wells.  A total of 102 soil samples and 6 groundwater samples were collected.  The exceedances are highlighted in Table 4.28.

Table 4.28     Analytical Result for Soil Samples of Outside Borings in Area 2

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

OB-16

0.18-0.38

Copper

637

OB-16

0.18-0.38

Nickel

469

OB-18

1.41-1.66

Copper

171

OB-18

1.41-1.66

Lead

300

OB-19

0.72-0.87

Copper

244

OB-20

0.07-0.22

Copper

276

OB-26

0.14-0.29

Benzo(a)pyrene

1.01

OB-26

0.14-0.29

Benzo(b)fluoranthene

0.98

OB-26

0.14-0.29

Copper

206

OB-26

0.14-0.29

Dibenz(a,h)anthracene

0.177

OB-27

0.08-0.23

Zinc

1340

OB-31

0.06-0.21

Copper

181

 

Surface Drainage Borings in Area 2 (SD)

4.132     A total of 38 soil samples were collected at 12 boring locations in Area 2.  The exceedances are tabulated in Table 4.29.

Table 4.29     Analytical Results for Soil Samples of Surface Drainage Borings in Area 2

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

SD-16

1.23-1.48

Zinc

545

SD-19a

2.0-2.25

Copper

111

SD-21

0.80-0.94

Benzo(a)anthracene

1.34

SD-21

0.80-0.94

Benzo(a)pyrene

1.9

SD-21

0.80-0.94

Benzo(b)fluoranthene

2.38

SD-21

0.80-0.94

Copper

115

SD-21

0.80-0.94

Dibenz(a,h)anthracene

0.657

SD-21

0.80-0.94

Indeno(1,2,3-cd)pyrene

1.51

SD-21

1.46-1.71

Lead

169

S-D22

0.30-0.45

Barium

858

 

Trenches for Debris Pile

4.133     Ten of the eleven trenches for debris pile were excavated in Area 2.  The exceedances are tabulated in Table 4.30.

Table 4.30     Analytical Results for Soil Samples of Debris Pile in Area 2

Trench Number

Depth (m)

Sample ID

Contaminant

Concentration (mg/kg or otherwise specified)

T5

0.96

T5/0.96m/3

TPH

14290

T6

0.96

T6/0.96m/5

Copper

393

T7

1.08

T7/1.08m/1

Copper

111

T7

1.47

T7/1.47m/3

Copper

162

T8

0.25

T8/0.25m/1

Cadmium

5

T8

0.25

T8/0.25m/1

Chromium

672

T8

0.25

T8/0.25m/1

Cobalt

67.8

T8

0.25

T8/0.25m/1

Copper

7080

T8

0.25

T8/0.25m/1

Lead

1310

T8

0.25

T8/0.25m/1

Nickel

726

T8

0.25

T8/0.25m/1

Tin

66.4

T8

0.25

T8/0.25m/1

Zinc

4350

T9

1.17

T9/1.17m/1

Barium

3290

T9

1.17

T9/1.17m/1

Chromium

477

T9

1.17

T9/1.17m/1

Copper

11400

T9

1.17

T9/1.17m/1

Lead

1300

T9

1.17

T9/1.17m/1

Nickel

497

T9

1.17

T9/1.17m/1

Tin

64.09

T9

0.92

T9/0.92m/5

Barium

1800

T9

0.92

T9/0.92m/5

Chromium

432

T9

0.92

T9/0.92m/5

Copper

4270

T9

0.92

T9/0.92m/5

Lead

881

T9

0.92

T9/0.92m/5

Nickel

487

T10

1.11

T10/1.11m/3

Copper

103

T10

0.79

T10/0.79m/5

Copper

222

T10

0.26

T10/0.26m/7

TPH

1297

T11

0.31

T11/0.31m/1

Styrene

6.3

 

Trenches for Burn Pit

4.134     A total of thirty-seven (37) main trenches for burn pit have been excavated and six of them were excavated in Area 2.  The exceedances are tabulated in Table 4.31.

Table 4.31     Analytical Results for Soil Samples of Burn Pit in Area 2

Trench No.

Transect

Sample ID

Contaminant

Conc. (mg/kg or otherwise specified)

IEC-T1

1-10

IEC-T1(1-10)/2.46m/1

Copper

408

IEC-T1

1-10

IEC-T1(1-10)/2.46m/1

Lead

1580

IEC-T1

1-10

IEC-T1(1-10)/1.3m/5

PCB

33.4

IEC-T1

1-10

IEC-T1(1-10)/1.3m/5

Copper

3850

IEC-T1

1-10

IEC-T1(1-10)/1.3m/5

Lead

509

IEC-T1

1-10

IEC-T1(1-10)/1.3m/5

Zinc

2150

IEC-T1

1-10

IEC-T1 (1-10)/1.9/7

Dioxins

1.400 ppb (TEQ)

IEC-T1

2-3

IEC-T1(2-3)/0.9m/21

PCB

5.7

IEC-T1

2-3

IEC-T1(2-3)/0.9m/21

TPH

1436

IEC-T1

2-3

IEC-T1(2-3)/0.9m/21

Copper

10300

IEC-T1

2-3

IEC-T1(2-3)/0.9m/21

Lead

359

IEC-T1

2-3

IEC-T1(2-3)/0.9m/21

Tin

64.09

IEC-T1

2-3

IEC-T1(2-3)/0.9m/21

Zinc

3650

IEC-T1

2-3

IEC-T1(2-3)/1.35m/23

Copper

140

IEC-T2

1-8

IEC-T2(1-8)/2.4m/1

Barium

1360

IEC-T2

1-8

IEC-T2(1-8)/2.4m/1

Copper

2400

IEC-T2

1-8

IEC-T2(1-8)/2.4m/1

Lead

1770

IEC-T2

1-8

IEC-T2(1-8)/2.4m/1

Nickel

159

IEC-T2

1-8

IEC-T2(1-8)/2.4m/1

Zinc

1190

IEC-T2

1-8

IEC-T2 (1-8)/2.4/1&2

Dioxins

1.020 ppb (TEQ)

IEC-T2

1-8

IEC-T2(1-8)/2.5m/7

Barium

524

IEC-T2

1-8

IEC-T2(1-8)/2.5m/7

Cadmium

12.9

IEC-T2

1-8

IEC-T2(1-8)/2.5m/7

Copper

27900

IEC-T2

1-8

IEC-T2(1-8)/2.5m/7

Lead

675

IEC-T2

1-8

IEC-T2(1-8)/2.5m/7

Nickel

239

IEC-T2

1-8

IEC-T2(1-8)/2.5m/7

Tin

232

IEC-T2

1-8

IEC-T2(1-8)/2.5m/7

Zinc

6840

IEC-T2

1-8

IEC-T2 (1-8)/2.5/7&8

Dioxins

3.990 ppb (TEQ)

IEC-T2

2-3

IEC-T2(2-3)/0.1m/13

Barium

2190

IEC-T2

2-3

IEC-T2(2-3)/0.1m/13

Cadmium

5.24

IEC-T2

2-3

IEC-T2(2-3)/0.1m/13

Chromium

350

IEC-T2

2-3

IEC-T2(2-3)/0.1m/13

Copper

5010

IEC-T2

2-3

IEC-T2(2-3)/0.1m/13

Lead

2010

IEC-T2

2-3

IEC-T2(2-3)/0.1m/13

Nickel

327

IEC-T2

2-3

IEC-T2(2-3)/0.1m/13

Zinc

3240

IEC-T2

2-3

IEC-T2 (2-3)/0.1/13

Dioxins

1.580 ppb (TEQ)

IEC-T2

4-5

IEC-T2(4-5)/1.5m/19

Barium

885

IEC-T2

4-5

IEC-T2(4-5)/1.5m/19

Copper

1470

IEC-T2

4-5

IEC-T2(4-5)/1.5m/19

Lead

1180

IEC-T2

4-5

IEC-T2(4-5)/1.5m/19

Zinc

1190

IEC-T2

4-5

IEC-T2 (4-5)/1.5/19&20

Dioxins

2.440 ppb (TEQ)

IEC-T2

4-5

IEC-T2(4-5)/1.0m/21

Barium

1880

IEC-T2

4-5

IEC-T2(4-5)/1.0m/21

Cadmium

6.11

IEC-T2

4-5

IEC-T2(4-5)/1.0m/21

Cobalt

50.8

IEC-T2

4-5

IEC-T2(4-5)/1.0m/21

Copper

5690

IEC-T2

4-5

IEC-T2(4-5)/1.0m/21

Lead

4630

IEC-T2

4-5

IEC-T2(4-5)/1.0m/21

Nickel

393

IEC-T2

4-5

IEC-T2(4-5)/1.0m/21

Tin

73.2

IEC-T2

4-5

IEC-T2(4-5)/1.0m/21

Zinc

5710

IEC-T2

4-5

IEC-T2 (4-5)/1.0/21&22

Dioxins

2.160  ppb (TEQ)

IEC-T2

6-7

IEC-T2(6-7)/0.8m/27

Barium

1340

IEC-T2

6-7

IEC-T2(6-7)/0.8m/27

Cadmium

5.36

IEC-T2

6-7

IEC-T2(6-7)/0.8m/27

Chromium

313

IEC-T2

6-7

IEC-T2(6-7)/0.8m/27

Copper

3840

IEC-T2

6-7

IEC-T2(6-7)/0.8m/27

Lead

1390

IEC-T2

6-7

IEC-T2(6-7)/0.8m/27

Nickel

234

IEC-T2

6-7

IEC-T2(6-7)/0.8m/27

Zinc

2340

IEC-T2

6-7

IEC-T2(6-7)/0.3m/31

Barium

1050

IEC-T2

6-7

IEC-T2(6-7)/0.3m/31

Cadmium

7.87

IEC-T2

6-7

IEC-T2(6-7)/0.3m/31

Chromium

655

IEC-T2

6-7

IEC-T2(6-7)/0.3m/31

Cobalt

56.5

IEC-T2

6-7

IEC-T2(6-7)/0.3m/31

Copper

9360

IEC-T2

6-7

IEC-T2(6-7)/0.3m/31

Lead

2000

IEC-T2

6-7

IEC-T2(6-7)/0.3m/31

Nickel

728

IEC-T2

6-7

IEC-T2(6-7)/0.3m/31

Tin

61

IEC-T2

6-7

IEC-T2(6-7)/0.3m/31

Zinc

5860

IEC-T2

6-7

IEC-T2 (6-7)/0.3/31&32

Dioxins

3.000 ppb (TEQ)

IEC-T3

1-8

IEC-T3(1-8)/0.3-0.45m/3

Barium

1470

IEC-T3

1-8

IEC-T3(1-8)/0.3-0.45m/3

Chromium

524

IEC-T3

1-8

IEC-T3(1-8)/0.3-0.45m/3

Copper

5570

IEC-T3

1-8

IEC-T3(1-8)/0.3-0.45m/3

Lead

1980

IEC-T3

1-8

IEC-T3(1-8)/0.3-0.45m/3

Nickel

357

IEC-T3

1-8

IEC-T3(1-8)/0.3-0.45m/3

Zinc

5570

IEC-T3

1-8

IEC-T3(1-8)0.65-0.8m/5

Barium

1060

IEC-T3

1-8

IEC-T3(1-8)0.65-0.8m/5

Chromium

307

IEC-T3

1-8

IEC-T3(1-8)0.65-0.8m/5

Copper

8070

IEC-T3

1-8

IEC-T3(1-8)0.65-0.8m/5

Lead

1140

IEC-T3

1-8

IEC-T3(1-8)0.65-0.8m/5

Nickel

411

IEC-T3

1-8

IEC-T3(1-8)0.65-0.8m/5

Tin

56.6

IEC-T3

1-8

IEC-T3(1-8)0.65-0.8m/5

Zinc

4830

IEC-T3

1-8

IEC-T3(1-8)/0.45m/9

Barium

771

IEC-T3

1-8

IEC-T3(1-8)/0.45m/9

Chromium

388

IEC-T3

1-8

IEC-T3(1-8)/0.45m/9

Copper

3590

IEC-T3

1-8

IEC-T3(1-8)/0.45m/9

Lead

1600

IEC-T3

1-8

IEC-T3(1-8)/0.45m/9

Nickel

343

IEC-T3

1-8

IEC-T3(1-8)/0.45m/9

Zinc

1960

IEC-T3

1-8

IEC-T3(1-8)/0.6m/13

Copper

134

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Barium

2220

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Cadmium

5.5

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Chromium

1670

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Cobalt

134

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Copper

10100

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Lead

2420

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Molybdenum

46

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Nickel

1380

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Tin

92.7

IEC-T3

2-3

IEC-T3(2-3)/0.65m/1

Zinc

8800

IEC-T4

1-8

IEC-T4(1-8)/3.0m/1

Lead

189

IEC-T4

4-5

IEC-T4(4-5)/3.4m/1

Lead

158

IEC-T6

1-6

IEC-T6(1-6)0.4m/5

Copper

1410

IEC-T6

1-6

IEC-T6(1-6)0.4m/5

Nickel

172

IEC-T6

1-6

IEC-T6(1-6)0.4m/5

Zinc

1210

 

Additional Boreholes in Area 2

4.135     Forty-three (43) additional boreholes have been drilled in Area 2 to delineate the soil contamination extent in this area more exactly.  The exceedances in the relevant standards are tabulated in Table 4.32.

Table 4.32     Analytical Results for Soil Samples of Additional Boreholes in Area 2

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

AB-43

0.80-0.95

Copper

191

AB-44

0.72-0.87

Copper

258

AB-46

0.07-0.22

Copper

225

AB-48

0.65-0.80

Copper

107

AB-50

0.08-0.23

Copper

7780

AB-50

0.08-0.23

Lead

2690

AB-50

0.08-0.23

Tin

167

AB-50

0.08-0.23

Zinc

1950

AB-50

0.80-0.95

Copper

3050

AB-50

0.80-0.95

Lead

3020

AB-50

0.80-0.95

Tin

156

AB-50

0.80-0.95

Zinc

790

AB-65

0.08-0.23

Copper

315

AB-65

0.65-0.80

Copper

223

AB-68

0.68-0.83

Lead

150

AB-68

0.68-0.83

Zinc

564

AB-70

0.65-0.80

Zinc

1270

AB-71

0.08-0.23

Lead

151

AB-71

0.08-0.23

Zinc

2070

AB-73

0.08-0.23

Copper

199

AB-80

0.65-0.80

Lead

162

AB-82

0.08-0.23

Copper

124

 

Additional Groundwater Monitoring Wells at Area 2

4.136     Seven (7) additional boreholes have been drilled in Area 2.  Groundwater monitoring wells were then installed at these locations.  The soil samples (taken from these boreholes) with exceedance in the relevant standards are summarised in Table 4.33.

Table 4.33     Analytical Results for Soil Samples of Additional Groundwater Wells in Area 2

 Borehole Location

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

AW-6

0.10-0.25

Copper

175

AW-6

0.10-0.25

Zinc

2500

 

4.137     The maximum and average concentrations of contaminants in Area 2 with exceedance in the relevant standards are given in Table 4.34.

Table 4.34     Maximum and Average Concentrations of Contaminants in Area 2 with Exceedance

 

 

Unit

No. of Exceedances

No. of Samples Analysed

Maximum

Average (exceedance only)

Overall Average

PCB

mg/kg

2

65

33.40

19.55

0.602

Barium

mg/kg

16

650

3290

1370

63.684

Benzo(a)anthracene

mg/kg

5

622

1.67

1.40

0.017

Benzo(a)pyrene

mg/kg

4

623

1.90

1.49

0.017

Benzo(b)fluoranthene

mg/kg

6

615

2.38

1.45

0.020

Bis(2-ethylhexyl)phthalate

mg/kg

1

623

46.00

46.00

0.109

Cadmium

mg/kg

7

654

13

7

0.160

TPH

mg/kg

11

654

14290

5353

118.800

Chromium

mg/kg

10

653

1670

579

14.412

Cobalt

mg/kg

4

650

134

77

4.274

Copper

mg/kg

56

654

27900

2549

227.167

Dibenz(a,h)anthracene

mg/kg

7

624

0.66

0.23

0.003

Indeno(1,2,3-cd)pyrene

mg/kg

3

623

1.51

1.17

0.014

Lead

mg/kg

31

657

4630

1182

105.991

Molybdenum

mg/kg

1

653

46

46

1.066

Nickel

mg/kg

15

654

1380

461

13.209

Styrene

mg/kg

1

616

6.30

6.30

0.010

Tin

mg/kg

10

657

232

103

2.092

Zinc

mg/kg

24

656

8800

2967

144.210

Dioxins

ppb (TEQ)

7

21

3.990

2.227

0.775

 

Area 3

4.138     Although the majority of Area 3 was not used for shipbuilding operations, it appears that it was used for disposal of wastes generated at the shipyard facility because many burn pits and buried wastes were encountered in exploratory trenches excavated in this area.  Many samples collected from the burn pits and monitoring well borings in this area were found to contain dioxins.   

Building Q

4.139     Fifty-one (51) soil samples were collected from 13 boreholes to assess contamination at Building Q.  The exceedances are summarised in Table 4.35.

Table 4.35     Analytical Results for Soil Samples of Building Q

Borehole Number

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

B-Q2

0.20-0.35

Copper

275

B-Q4

0.10-0.25

TPH

9122

B-Q7

0.08-0.23

Copper

142

B-Q7

0.68-0.83

Copper

438

B-Q7

1.38-1.63

Copper

566

B-Q7

1.38-1.63

Lead

278

B-Q14

0.22-0.38

TPH

2614

B-Q15

0.24-0.39

TPH

3031

 

Trenches for Burn Pit

4.140     Thirty-one (31) main trenches for burn pit were excavated in Area 3.  The exceedances are tabulated in Table 4.36.

Table 4.36     Analytical Results for Soil Samples of Burn Pit in Area 3

Trench No.

Transect

Sample ID

Contaminant

Conc. (mg/kg or otherwise specified)

IEC-T7

2-3

IEC-T7(2-3)/1.2m/9

Lead

183

IEC-T7

2-3

IEC-T7(2-3)0.6m/13

Lead

184

IEC-T9

1-10

IEC-T9(1-10)/1.27m/5

Barium

643

IEC-T9

1-10

IEC-T9(1-10)/1.27m/5

Cadmium

10.2

IEC-T9

1-10

IEC-T9(1-10)/1.27m/5

Copper

1510

IEC-T9

1-10

IEC-T9(1-10)/1.27m/5

Lead

296

IEC-T9

1-10

IEC-T9(1-10)/1.27m/5

Zinc

2000

IEC-T9

1-10

IEC-T9 (1-10)/1.27/5

Dioxins

14.900 ppb (TEQ)

IEC-T9

1-10

IEC-T9(1-10)/0.84m/9

Barium

538

IEC-T9

1-10

IEC-T9(1-10)/0.84m/9

Cadmium

6.42

IEC-T9

1-10

IEC-T9(1-10)/0.84m/9

Copper

819

IEC-T9

1-10

IEC-T9(1-10)/0.84m/9

Lead

412

IEC-T9

1-10

IEC-T9(1-10)/0.84m/9

Nickel

103

IEC-T9

1-10

IEC-T9(1-10)/0.84m/9

Zinc

5860

IEC-T9

1-10

IEC-T9 (1-10)/0.84/9

Dioxins

1.550 ppb (TEQ)

IEC-T9

8-9

IEC-T9(8-9)/0.4m/13

Copper

837

IEC-T9

8-9

IEC-T9(8-9)/0.4m/13

Lead

179

IEC-T9

8-9

IEC-T9(8-9)/0.4m/13

Nickel

214

IEC-T9

8-9

IEC-T9(8-9)/0.4m/13

Zinc

1110

IEC-T9

8-9

IEC-T9(8-9)/1.91m/17

Cadmium

7.38

IEC-T9

8-9

IEC-T9(8-9)/1.91m/17

Chromium

984

IEC-T9

8-9

IEC-T9(8-9)/1.91m/17

Cobalt

328

IEC-T9

8-9

IEC-T9(8-9)/1.91m/17

Copper

28100

IEC-T9

8-9

IEC-T9(8-9)/1.91m/17

Lead

2000

IEC-T9

8-9

IEC-T9(8-9)/1.91m/17

Molybdenum

599

IEC-T9

8-9

IEC-T9(8-9)/1.91m/17

Nickel

1790

IEC-T9

8-9

IEC-T9(8-9)/1.91m/17

Tin

107

IEC-T9

8-9

IEC-T9(8-9)/1.91m/17

Zinc

23400

IEC-T9

8-9

IEC-T9 (8-9)/1.91/17

Dioxins

1.500 ppb (TEQ)

IEC-T11

1-2

IEC-T11(1-2)/1.1m/7

Copper

534

IEC-T11

1-2

IEC-T11(1-2)/1.1m/7

Lead

401

IEC-T11

1-2

IEC-T11(1-2)/1.1m/7

Zinc

885

IEC-T11

1-2

IEC-T11(1-2)/0.9m/11

Copper

294

IEC-T11

1-2

IEC-T11(1-2)/0.9m/11

Lead

1060

IEC-T11

1-2

IEC-T11(1-2)/0.9m/11

Nickel

108

IEC-T11

1-2

IEC-T11(1-2)/0.9m/11

Zinc

682

IEC-T11

1-2

IEC-T11(1-2)/3.3m/13

Lead

254

IEC-T11

1-2

IEC-T11(1-2)/1.0m/15

Copper

408

IEC-T11

3-4

IEC-T11(3-4)/1.8m/3

Arsenic

42

IEC-T11

3-4

IEC-T11(3-4)/1.8m/3

Cadmium

6.21

IEC-T11

3-4

IEC-T11(3-4)/1.8m/3

TPH

1617

IEC-T11

3-4

IEC-T11(3-4)/1.8m/3

Chromium

890

IEC-T11

3-4

IEC-T11(3-4)/1.8m/3

Copper

5300

IEC-T11

3-4

IEC-T11(3-4)/1.8m/3

Lead

590

IEC-T11

3-4

IEC-T11(3-4)/1.8m/3

Nickel

280

IEC-T11

3-4

IEC-T11(3-4)/1.8m/3

Zinc

2870

IEC-T12

1-2

IEC-T12(1-2)/1.6m/1

Barium

442

IEC-T12

1-2

IEC-T12(1-2)/1.6m/1

Copper

3220

IEC-T12

1-2

IEC-T12(1-2)/1.6m/1

Lead

181

IEC-T12

1-2

IEC-T12(1-2)/1.6m/1

Nickel

123

IEC-T12

1-2

IEC-T12 (1-2)/1.6m/1

Dioxins

4.545 ppb (TEQ)

IEC-T12

1-2

IEC-T12(1-2)/1.4m/3

Copper

485

IEC-T12

1-2

IEC-T12(1-2)/1.4m/3

Lead

168

IEC-T12

1-2

IEC-T12(1-2)/1.8m/7

Copper

5770

IEC-T12

1-2

IEC-T12(1-2)/1.8m/7

Dibenz(a,h)anthracene

0.169

IEC-T12

1-2

IEC-T12(1-2)/1.8m/7

Lead

307

IEC-T12

1-2

IEC-T12(1-2)/1.8m/7

Nickel

222

IEC-T12

1-2

IEC-T12(1-2)/1.8m/7

Zinc

997

IEC-T12

1-2

IEC-T12 (1-2)/1.8m/7

Dioxins

1.218 ppb (TEQ)

IEC-T12

3-4

IEC-T12 (3-4)/4.1/1&2

Dioxins

5.060 ppb (TEQ)

IEC-T12

3-4

IEC-T12(3-4)/2.0m/4

Lead

188

IEC-T12

3-4

IEC-T12 (3-4)/1.8/5&6

Dioxins

1.570 ppb (TEQ)

IEC-T12

5-6

IEC-T12(5-6)/2.5m/1

Copper

158

IEC-T12

9-10

IEC-T12(9-10)/1.80m/5

Copper

1900

IEC-T12

9-10

IEC-T12(9-10)/1.80m/5

Nickel

159

IEC-T12

9-10

IEC-T12(9-10)/1.80m/5

Zinc

954

IEC-T12

9-10

IEC-T12 (9-10)/1.8m/5

Dioxins

3.548 ppb (TEQ)

IEC-T13

1-2

IEC-T13(1-2)/1.5m/1

Zinc

543

IEC-T13

1-2

IEC-T13(1-2)/0.6m/7

Lead

335

IEC-T13

7-8

IEC-T13(7-8)/2.4m/5

Arsenic

114

IEC-T13

7-8

IEC-T13(7-8)/2.4m/5

Barium

619

IEC-T13

7-8

IEC-T13(7-8)/2.4m/5

Chromium

524

IEC-T13

7-8

IEC-T13(7-8)/2.4m/5

Copper

619

IEC-T13

7-8

IEC-T13(7-8)/2.4m/5

Lead

2410

IEC-T13

7-8

IEC-T13(7-8)/2.4m/5

Nickel

907

IEC-T13

7-8

IEC-T13(7-8)/2.4m/5

Tin

50.1

IEC-T13

7-8

IEC-T13(7-8)/2.4m/5

Zinc

2940

IEC-T13

7-8

IEC-T13(7-8)/2.1m/9

Antimony

101

IEC-T13

7-8

IEC-T13(7-8)/2.1m/9

Zinc

28900

IEC-T18

3-4

IEC-T18(3-4)/1.4m/5

Copper

2100

IEC-T18

3-4

IEC-T18(3-4)/1.4m/5

Lead

278

IEC-T19

1-2

IEC-T19(1-2)/1.03m/1

Copper

7490

IEC-T19

1-2

IEC-T19(1-2)/1.03m/1

Lead

624

IEC-T19

1-2

IEC-T19(1-2)/1.03m/1

Nickel

114

IEC-T19

1-2

IEC-T19(1-2)/1.03m/1

Zinc

2150

IEC-T19

1-2

IEC-T19(1-2)/3.5m/5

Chromium

1110

IEC-T19

1-2

IEC-T19(1-2)/3.5m/5

Copper

643

IEC-T19

1-2

IEC-T19(1-2)/3.5m/5

Lead

215

IEC-T19

1-2

IEC-T19(1-2)/3.5m/5

Zinc

602

IEC-T19

3-4

IEC-T19(3-4)/1.0m/1

Barium

1780

IEC-T19

3-4

IEC-T19(3-4)/1.0m/1

Copper

202

IEC-T19

3-4

IEC-T19(3-4)/1.0m/1

Lead

825

IEC-T19

5-6

IEC-T19(5-6)/1.1m/1

Copper

1150

IEC-T19

5-6

IEC-T19(5-6)/1.1m/1

Lead

685

IEC-T19

5-6

IEC-T19(5-6)/1.1m/1

Zinc

706

IEC-T19

5-6

IEC-T19 (5-6)/1.1m/1

Dioxins

1.040 ppb (TEQ)

IEC-T19

5-6

IEC-T19(5-6)/1.9m/5

Arsenic

36

IEC-T19

5-6

IEC-T19(5-6)/1.9m/5

Cadmium

8.17

IEC-T19

5-6

IEC-T19(5-6)/1.9m/5

Chromium

266

IEC-T19

5-6

IEC-T19(5-6)/1.9m/5

Copper

4050

IEC-T19

5-6

IEC-T19(5-6)/1.9m/5

Lead

3110

IEC-T19

5-6

IEC-T19(5-6)/1.9m/5

Nickel

331

IEC-T19

5-6

IEC-T19(5-6)/1.9m/5

Tin

67.5

IEC-T19

5-6

IEC-T19(5-6)/1.9m/5

Zinc

3910

IEC-T19

5-6

IEC-T19(5-6)/1.3m/9

Copper

388

IEC-T19

7-8

IEC-T19(7-8)/2.4m/7

Chromium

516

IEC-T19

7-8

IEC-T19(7-8)/2.4m/7

Copper

6300

IEC-T19

7-8

IEC-T19(7-8)/2.4m/7

Lead

424

IEC-T19

7-8

IEC-T19(7-8)/2.4m/7

Nickel

285

IEC-T19

7-8

IEC-T19(7-8)/2.4m/7

Zinc

2230

IEC-T20

1-2

IEC-T20 (1-2)/1.6m/2

Dioxins

1.148 ppb (TEQ)

IEC-T20

1-2

IEC-T20(1-2)/2.8m/3

Copper

117

IEC-T20

1-2

IEC-T20(1-2)/1.6m/5

Copper

137

IEC-T20

1-2

IEC-T20(1-2)/1.3m/7

Copper

142

IEC-T20

1-2

IEC-T20(1-2)/1.3m/9

Barium

3100

IEC-T20

1-2

IEC-T20(1-2)/1.3m/9

Cobalt

51.4

IEC-T20

1-2

IEC-T20(1-2)/1.3m/9

Copper

3310

IEC-T20

1-2

IEC-T20(1-2)/1.3m/9

Lead

860

IEC-T20

1-2

IEC-T20(1-2)/1.3m/9

Nickel

234

IEC-T20

1-2

IEC-T20(1-2)/1.3m/9

Zinc

3610

IEC-T20

1-2

IEC-T20 (1-2)/1.3m/9

Dioxins

1.067 ppb (TEQ)

IEC-T20

1-2

IEC-T20(1-2)/2.2m/11

Barium

1820

IEC-T20

1-2

IEC-T20(1-2)/2.2m/11

Copper

3450

IEC-T20

1-2

IEC-T20(1-2)/2.2m/11

Lead

1380

IEC-T20

1-2

IEC-T20(1-2)/2.2m/11

Nickel

170

IEC-T20

1-2

IEC-T20(1-2)/2.2m/11

Zinc

1810

IEC-T20

1-2

IEC-T20(1-2)/2.2m/11

Dioxins

1.473 ppb (TEQ)

IEC-T20

1-2

IEC-T20(1-2)/2.2m/13

Dioxins

5.393 ppb (TEQ)

IEC-T20

3-4

IEC-T20(3-4)/3.9m/5

Barium

4660

IEC-T20

3-4

IEC-T20(3-4)/3.9m/5

Copper

5470

IEC-T20

3-4

IEC-T20(3-4)/3.9m/5

Lead

1500

IEC-T20

3-4

IEC-T20(3-4)/3.9m/5

Nickel

352

IEC-T20

3-4

IEC-T20(3-4)/3.9m/5

Tin

64.6

IEC-T20

3-4

IEC-T20(3-4)/3.9m/5

Zinc

3020

IEC-T20

3-4

IEC-T20 (3-4)/3.9m/6

Dioxins

1.882 ppb (TEQ)

IEC-T20

3-4

IEC-T20(3-4)/3.8m/9

Barium

3520

IEC-T20

3-4

IEC-T20(3-4)/3.8m/9

Copper

4590

IEC-T20

3-4

IEC-T20(3-4)/3.8m/9

Lead

1670

IEC-T20

3-4

IEC-T20(3-4)/3.8m/9

Nickel

262

IEC-T20

3-4

IEC-T20(3-4)/3.8m/9

Tin

81.1

IEC-T20

3-4

IEC-T20(3-4)/3.8m/9

Zinc

2910

IEC-T20

3-4

IEC-T20 (3-4)/3.8m/10

Dioxins

1.776 ppb (TEQ)

IEC-T20

3-4

IEC-T20(3-4)/2.0m/19

Copper

790

IEC-T20

3-4

IEC-T20(3-4)/2.0m/19

Lead

689

IEC-T20

3-4

IEC-T20(3-4)/2.0m/19

Zinc

559

IEC-T20

5-6

IEC-T20(5-6)/3.5m/1

TPH

15094

IEC-T20

5-6

IEC-T20(5-6)/3.5m/1

Copper

233

IEC-T20

5-6

IEC-T20(5-6)/3.5m/1

Lead

237

IEC-T20

5-6

IEC-T20 (5-6)/3.5m/1

Dioxins

1.461 ppb (TEQ)

IEC-T20

5-6

IEC-T20(5-6)/1.4m/9

Barium

2050

IEC-T20

5-6

IEC-T20(5-6)/1.4m/9

Copper

4470

IEC-T20

5-6

IEC-T20(5-6)/1.4m/9

Lead

1300

IEC-T20

5-6

IEC-T20(5-6)/1.4m/9

Nickel

471

IEC-T20

5-6

IEC-T20(5-6)/1.4m/9

Zinc

2370

IEC-T20

5-6

IEC-T20 (5-6)/1.4m/10

Dioxins

3.457 ppb (TEQ)

IEC-T20

5-6

IEC-T20(5-6)/2.0m/11

Lead

227

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Antimony

340

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Bis(2-ethylhexyl)phthalate

563

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Cadmium

118

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

TPH

88482

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Chromium

412

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Cobalt

69

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Copper

14100

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Lead

21100

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Nickel

664

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Tin

3650

IEC-T20

5-6

IEC-T20(5-6)/2.0m/13

Zinc

35700

IEC-T20

7-8

IEC-T20(7-8)/4.5m/1

Chromium

5390

IEC-T20

7-8

IEC-T20(7-8)/4.5m/1

Copper

4080

IEC-T20

7-8

IEC-T20(7-8)/4.5m/1

Lead

867

IEC-T20

7-8

IEC-T20(7-8)/4.5m/1

Nickel

108

IEC-T20

7-8

IEC-T20(7-8)/4.5m/1

Zinc

1690

IEC-T20

7-8

IEC-T20 (7-8)/4.5m/1

Dioxins

1.333 ppb (TEQ)

IEC-T20

7-8

IEC-T20(7-8)/2.0m/5

Chromium

798

IEC-T20

7-8

IEC-T20(7-8)/2.0m/5

Copper

780

IEC-T20

7-8

IEC-T20(7-8)/2.0m/5

Lead

418

IEC-T20

7-8

IEC-T20(7-8)/2.0m/5

Nickel

706

IEC-T20

7-8

IEC-T20(7-8)/2.0m/5

Zinc

509

IEC-T20

7-8

IEC-T20(7-8)/2.0m/5

Dioxins

1.767 ppb (TEQ)

IEC-T20

9-10

IEC-T20(9-10)/1.5m/3

Lead

170

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Antimony

35.5

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Barium

1180

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Chromium

703

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Cobalt

59

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Copper

3960

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Lead

1140

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Molybdenum

56.6

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Nickel

906

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Tin

50.6

IEC-T20

9-10

IEC-T20(9-10)/1.0m/5

Zinc

3590

IEC-T20

9-10

IEC-T20 (9-10)/1.0m/5

Dioxins

7.572 ppb (TEQ)

IEC-T20

9-10

IEC-T20(9-10)/2.6m/7

Copper

259

IEC-T21

1-2

IEC-T21(1-2)/1.4m/1

Copper

789

IEC-T21

1-2

IEC-T21(1-2)/1.4m/1

Lead

160

IEC-T21

1-2

IEC-T21(1-2)/2.9m/3

Barium

617

IEC-T21

1-2

IEC-T21(1-2)/2.9m/3

Copper

490

IEC-T21

1-2

IEC-T21(1-2)/2.9m/3

Lead

193

IEC-T21

1-2

IEC-T21(1-2)/2.9m/3

Nickel

215

IEC-T21

1-2

IEC-T21(1-2)/2.9m/3

Tin

169

IEC-T21

1-2

IEC-T21(1-2)/1.0m/5

Copper

110

IEC-T21

1-2

IEC-T21(1-2)/1.4m/13

Copper

10300

IEC-T21

1-2

IEC-T21(1-2)/1.4m/13

Hexachlorobenzene

1

IEC-T21

1-2

IEC-T21(1-2)/1.4m/13

Lead

182

IEC-T21

1-2

IEC-T21(1-2)/1.4m/13

Nickel

767

IEC-T21

1-2

IEC-T21(1-2)/1.4m/13

Zinc

2190

IEC-T21

1-2

IEC-T21 (1-2)/1.4m/14

Dioxins

14.084 ppb (TEQ)

IEC-T21

1-2

IEC-T21(1-2)/2.6m/15

Barium

1690

IEC-T21

1-2

IEC-T21(1-2)/2.6m/15

Chromium

266

IEC-T21

1-2

IEC-T21(1-2)/2.6m/15

Cobalt

65.1

IEC-T21

1-2

IEC-T21(1-2)/2.6m/15

Copper

3420

IEC-T21

1-2

IEC-T21(1-2)/2.6m/15

Lead

256

IEC-T21

1-2

IEC-T21(1-2)/2.6m/15

Nickel

337

IEC-T21

1-2

IEC-T21(1-2)/2.6m/15

Tin

55

IEC-T21

1-2

IEC-T21(1-2)/2.6m/15

Zinc

1700

IEC-T21

1-2

IEC-T21 (1-2)/2.6m/16

Dioxins

1.212 ppb (TEQ)

IEC-T21

3-4

IEC-T21(3-4)/1.5m/1

Arsenic

36

IEC-T21

3-4

IEC-T21(3-4)/1.5m/1

Barium

431

IEC-T21

3-4

IEC-T21(3-4)/1.5m/1

Chromium

252

IEC-T21

3-4

IEC-T21(3-4)/1.5m/1

Copper

3590

IEC-T21

3-4

IEC-T21(3-4)/1.5m/1

Lead

751

IEC-T21

3-4

IEC-T21(3-4)/1.5m/1

Nickel

411

IEC-T21

3-4

IEC-T21(3-4)/1.5m/1

Zinc

919

IEC-T21

3-4

IEC-T21 (3-4)/1.5m/(1,2)

Dioxins

1.467 ppb (TEQ)

IEC-T21

3-4

IEC-T21(3-4)/2.6m/3

Copper

5230

IEC-T21

3-4

IEC-T21(3-4)/2.6m/3

Lead

241

IEC-T21

3-4

IEC-T21(3-4)/2.6m/3

Nickel

269

IEC-T21

3-4

IEC-T21(3-4)/2.6m/3

Zinc

782

IEC-T21

3-4

IEC-T21 (3-4)/2.6m/3

Dioxins

2.948 ppb (TEQ)

IEC-T21

3-4

IEC-T21(3-4)/1.6m/5

Lead

183

IEC-T21

3-4

IEC-T21(3-4)/1.4m/7

Copper

3430

IEC-T21

3-4

IEC-T21(3-4)/1.4m/7

Lead

583

IEC-T21

3-4

IEC-T21(3-4)/1.4m/7

Nickel

286

IEC-T21

3-4

IEC-T21(3-4)/1.4m/7

Zinc

2140

IEC-T21

3-4

IEC-T21 (3-4)/1.4m/(7,8)

Dioxins

23.596  (TEQ)

IEC-T21

9-10

IEC-T21(9-10)/3.0m/5

Copper

315

IEC-T21

9-10

IEC-T21(9-10)/3.0m/5

Dibenz(a,h)anthracene

0.092

IEC-T21

9-10

IEC-T21(9-10)/3.0m/5

Nickel

155

IEC-T21

9-10

IEC-T21(9-10)/3.0m/5

Zinc

3180

IEC-T22

1-2

IEC-T22(1-2)/2.3m/1

Copper

274

IEC-T22

1-2

IEC-T22(1-2)/2.3m/1

Lead

3340

IEC-T22

1-2

IEC-T22(1-2)/1.4m/5

Copper

863

IEC-T22

1-2

IEC-T22(1-2)/1.4m/5

Lead

162

IEC-T22

1-2

IEC-T22(1-2)/1.4m/5

Zinc

730

IEC-T22

1-2

IEC-T22(1-2)/2.9m/7

Copper

361

IEC-T22

1-2

IEC-T22(1-2)/1.1m/13

Barium

4330

IEC-T22

1-2

IEC-T22(1-2)/1.1m/13

Cobalt

63.3

IEC-T22

1-2

IEC-T22(1-2)/1.1m/13

Copper

4830

IEC-T22

1-2

IEC-T22(1-2)/1.1m/13

Lead

6580

IEC-T22

1-2

IEC-T22(1-2)/1.1m/13

Nickel

295

IEC-T22

1-2

IEC-T22(1-2)/1.1m/13

Tin

51.7

IEC-T22

1-2

IEC-T22(1-2)/1.1m/13

Zinc

3350

IEC-T22

1-2

IEC-T22(1-2)/1.5m/15

Copper

137

IEC-T22

1-2

IEC-T22(1-2)/1.5m/15

Tin

51

IEC-T22

4-3

IEC-T22(4-3)/1.5m/1

Arsenic

37.9

IEC-T22

4-3

IEC-T22(4-3)/1.5m/1

Barium

401

IEC-T22

4-3

IEC-T22(4-3)/1.5m/1

Cadmium

6.7

IEC-T22

4-3

IEC-T22(4-3)/1.5m/1

Chromium

299

IEC-T22

4-3

IEC-T22(4-3)/1.5m/1

Copper

4950

IEC-T22

4-3

IEC-T22(4-3)/1.5m/1

Lead

5060

IEC-T22

4-3

IEC-T22(4-3)/1.5m/1

Nickel

299

IEC-T22

4-3

IEC-T22(4-3)/1.5m/1

Tin

90.2

IEC-T22

4-3

IEC-T22(4-3)/1.5m/1

Zinc

4230

IEC-T22

4-3

IEC-T22(4-3)/3.8m/3

TPH

1695

IEC-T22

4-3

IEC-T22(4-3)/1.1m/5

Copper

1210

IEC-T22

4-3

IEC-T22(4-3)/1.1m/5

Lead

174

IEC-T22

4-3

IEC-T22(4-3)/1.1m/5

Zinc

803

IEC-T22

4-3

IEC-T22 (4-3)/1.1m/5

Dioxins

1.018 ppb (TEQ)

IEC-T22

6-5

IEC-T22(6-5)/1.4m/5

Antimony

35.2

IEC-T22

6-5

IEC-T22(6-5)/1.4m/5

Chromium

284

IEC-T22

6-5

IEC-T22(6-5)/1.4m/5

Copper

876

IEC-T22

6-5

IEC-T22(6-5)/1.4m/5

Lead

168

IEC-T22

6-5

IEC-T22(6-5)/1.4m/5

Molybdenum

353

IEC-T22

6-5

IEC-T22(6-5)/1.4m/5

Nickel

726

IEC-T22

6-5

IEC-T22(6-5)/1.4m/5

Zinc

2900

IEC-T22

6-5

IEC-T22(6-5)/2.9m/7

Barium

554

IEC-T22

6-5

IEC-T22(6-5)/2.9m/7

Chromium

1520

IEC-T22

6-5

IEC-T22(6-5)/2.9m/7

Cobalt

62.1

IEC-T22

6-5

IEC-T22(6-5)/2.9m/7

Copper

5670

IEC-T22

6-5

IEC-T22(6-5)/2.9m/7

Lead

8460

IEC-T22

6-5

IEC-T22(6-5)/2.9m/7

Molybdenum

84.2

IEC-T22

6-5

IEC-T22(6-5)/2.9m/7

Nickel

1450

IEC-T22

6-5

IEC-T22(6-5)/2.9m/7

Zinc

4470

IEC-T22

6-5

IEC-T22(6-5)/1.2m/11

TPH

1377

IEC-T22

6-5

IEC-T22(6-5)/1.2m/11

Copper

908

IEC-T22

6-5

IEC-T22(6-5)/1.2m/11

Lead

170

IEC-T22

6-5

IEC-T22(6-5)/1.2m/11

Zinc

640

IEC-T22

7-8

IEC-T22(7-8)/1.4m/1

Barium

862

IEC-T22

7-8

IEC-T22(7-8)/1.4m/1

TPH

1022

IEC-T22

7-8

IEC-T22(7-8)/1.4m/1

Copper

14900

IEC-T22

7-8

IEC-T22(7-8)/1.4m/1

Lead

1450

IEC-T22

7-8

IEC-T22(7-8)/1.4m/1

Nickel

162

IEC-T22

7-8

IEC-T22(7-8)/1.4m/1

Zinc

3170

IEC-T22

7-8

IEC-T22 (7-8)/1.4m/1

Dioxins

6.268 ppb (TEQ)

IEC-T22

7-8

IEC-T22(7-8)/2.8m/3

Barium

452

IEC-T22

7-8

IEC-T22(7-8)/2.8m/3

Copper

3670

IEC-T22

7-8

IEC-T22(7-8)/2.8m/3

Lead

402

IEC-T22

7-8

IEC-T22(7-8)/2.8m/3

Tin

56.5

IEC-T22

7-8

IEC-T22(7-8)/1.4m/5

Cobalt

108

IEC-T22

7-8

IEC-T22(7-8)/1.4m/5

Copper

4230

IEC-T22

7-8

IEC-T22(7-8)/1.4m/5

Lead

856

IEC-T22

7-8

IEC-T22(7-8)/1.4m/5

Nickel

197

IEC-T22

7-8

IEC-T22(7-8)/1.4m/5

Tin

55.5

IEC-T22

7-8

IEC-T22(7-8)/1.4m/5

Zinc

4930

IEC-T25

1-2

IEC-T25(1-2)/1.4m/3

Barium

486

IEC-T25

1-2

IEC-T25(1-2)/1.4m/3

Lead

155

IEC-T26

1-2

IEC-T26(1-2)/0.7m/9

Lead

182

IEC-T26

3-4

IEC-T26(3-4)/0.9m/3

Copper

173

IEC-T26

3-4

IEC-T26(3-4)/0.9m/3

Lead

178

IEC-T26

3-4

IEC-T26(3-4)/0.55m/7

Copper

207

IEC-T29

3-4

IEC-T29(3-4)/1.4m/1

Chromium

2740

IEC-T29

3-4

IEC-T29(3-4)/1.4m/1

Cobalt

57.6

IEC-T29

3-4

IEC-T29(3-4)/1.4m/1

Copper

3310

IEC-T29

3-4

IEC-T29(3-4)/1.4m/1

Lead

174

IEC-T29

3-4

IEC-T29(3-4)/1.4m/1

Nickel

1210

IEC-T29

3-4

IEC-T29(3-4)/1.4m/1

Zinc

1050

IEC-T30

2-1

IEC-T30(2-1)/1.2m/9

PCB

0.7

IEC-T30

2-1

IEC-T30(2-1)/1.2m/9

Chromium

343

IEC-T30

2-1

IEC-T30(2-1)/1.2m/9

Copper

3190

IEC-T30

2-1

IEC-T30(2-1)/1.2m/9

Lead

2760

IEC-T30

2-1

IEC-T30(2-1)/1.2m/9

Nickel

368

IEC-T30

2-1

IEC-T30(2-1)/1.2m/9

Zinc

3390

IEC-T30

2-1

IEC-T30(2-1)/2.3m/11

Copper

2300

IEC-T30

3-4

IEC-T30(3-4)/0.6m/7

TPH

3816

IEC-T31

1-2

IEC-T31(1-2)/0.2m/1

TPH

2031

IEC-T33

3-4

IEC-T33(3-4)/4.6m/1

TPH

4474

IEC-T33

3-4

IEC-T33(3-4)/1.8m/5

Copper

2300

IEC-T33

3-4

IEC-T33(3-4)/1.8m/5

Zinc

1210

IEC-T35

2-1

IEC-T35(2-1)/1.2m/5

Cadmium

12

IEC-T35

2-1

IEC-T35(2-1)/1.2m/5

Cobalt

132

IEC-T35

2-1

IEC-T35(2-1)/1.2m/5

Copper

3020

IEC-T35

2-1

IEC-T35(2-1)/1.2m/5

Lead

834

IEC-T35

2-1

IEC-T35(2-1)/1.2m/5

Nickel

107

IEC-T35

2-1

IEC-T35(2-1)/1.2m/5

Zinc

3170

IEC-T35

2-1

IEC-T35 (2-1)/1.2m/6

Dioxins

7.946 ppb (TEQ)

IEC-T35

2-1

IEC-T35(2-1)/2.5m/9

Chromium

269

IEC-T35

2-1

IEC-T35(2-1)/2.5m/9

Copper

4700

IEC-T35

2-1

IEC-T35(2-1)/2.5m/9

Lead

491

IEC-T35

2-1

IEC-T35(2-1)/2.5m/9

Nickel

245

IEC-T35

2-1

IEC-T35(2-1)/2.5m/9

Zinc

4300

IEC-T35

5-6

IEC-T35(5-6)/1.1m/1

Copper

903

IEC-T35

5-6

IEC-T35(5-6)/1.1m/1

Lead

269

IEC-T35

5-6

IEC-T35(5-6)/1.1m/1

Nickel

177

IEC-T35

5-6

IEC-T35(5-6)/1.1m/1

Zinc

1560

IEC-T36

1-2

IEC-T36(1-2)/0.6m/5

Lead

151

IEC-T36

1-2

IEC-T36(1-2)/2.0m/11

Cadmium

5.89

IEC-T36

1-2

IEC-T36(1-2)/2.0m/11

Chromium

793

IEC-T36

1-2

IEC-T36(1-2)/2.0m/11

Copper

2660

IEC-T36

1-2

IEC-T36(1-2)/2.0m/11

Lead

6090

IEC-T36

1-2

IEC-T36(1-2)/2.0m/11

Nickel

1590

IEC-T36

1-2

IEC-T36(1-2)/2.0m/11

Tin

175

IEC-T36

1-2

IEC-T36(1-2)/2.0m/11

Zinc

6290

IEC-T36

7-8

IEC-T36(7-8)/0.9m/1

Copper

2970

IEC-T36

7-8

IEC-T36(7-8)/0.9m/1

Lead

274

IEC-T36

7-8

IEC-T36(7-8)/0.9m/1

Zinc

3070

IEC-T36

9-10

IEC-T36(9-10)/1.8m/5

Cobalt

88.8

IEC-T36

9-10

IEC-T36(9-10)/1.8m/5

Copper

3250

IEC-T36

9-10

IEC-T36(9-10)/1.8m/5

Lead

1320

IEC-T36

9-10

IEC-T36(9-10)/1.8m/5

Nickel

405

IEC-T36

9-10

IEC-T36(9-10)/1.8m/5

Zinc

1790

IEC-T36

11-12

IEC-T36(11-12)/3.1m/1

Chromium

615

IEC-T36

11-12

IEC-T36(11-12)/3.1m/1

Cobalt

103

IEC-T36

11-12

IEC-T36(11-12)/3.1m/1

Copper

5410

IEC-T36

11-12

IEC-T36(11-12)/3.1m/1

Lead

898

IEC-T36

11-12

IEC-T36(11-12)/3.1m/1

Nickel

803

IEC-T36

11-12

IEC-T36(11-12)/3.1m/1

Tin

113

IEC-T36

11-12

IEC-T36(11-12)/3.1m/1

Zinc

3440

IEC-T36

11-12

IEC-T36(11-12)/4.0m/3

Copper

257

IEC-T36

11-12

IEC-T36(11-12)/4.0m/3

Lead

255

IEC-T37

1-2

IEC-T37(1-2)/1.5m/7

Barium

1480

IEC-T37

1-2

IEC-T37(1-2)/1.5m/7

Copper

2650

IEC-T37

1-2

IEC-T37(1-2)/1.5m/7

Lead

4080

IEC-T37

1-2

IEC-T37(1-2)/1.5m/7

Nickel

188

IEC-T37

1-2

IEC-T37(1-2)/1.5m/7

Zinc

7840

IEC-T37

1-2

IEC-T37(1-2)/1.0m/9

Copper

116

IEC-T37

1-2

IEC-T37(1-2)/2.9m/11

Barium

986

IEC-T37

1-2

IEC-T37(1-2)/2.9m/11

Copper

2970

IEC-T37

1-2

IEC-T37(1-2)/2.9m/11

Lead

921

IEC-T37

1-2

IEC-T37(1-2)/2.9m/11

Nickel

171

IEC-T37

1-2

IEC-T37(1-2)/2.9m/11

Tin

71.3

IEC-T37

1-2

IEC-T37(1-2)/2.9m/11

Zinc

2060

IEC-T37

1-2

IEC-T37(1-2)/0.6m/13

Copper

887

IEC-T37

1-2

IEC-T37(1-2)/3.3m/15

Copper

117

IEC-T37

3-4

IEC-T37(3-4)/0.6m/1

Lead

213

IEC-T37

3-4

IEC-T37(3-4)/2.4m/3

Copper

337

IEC-T37

6-5

IEC-T37(6-5)/0.8m/5

Barium

2220

IEC-T37

6-5

IEC-T37(6-5)/0.8m/5

TPH

8668

IEC-T37

6-5

IEC-T37(6-5)/0.8m/5

Copper

6050

IEC-T37

6-5

IEC-T37(6-5)/0.8m/5

Lead

599

IEC-T37

6-5

IEC-T37(6-5)/0.8m/5

Nickel

191

IEC-T37

6-5

IEC-T37(6-5)/0.8m/5

Zinc

1330

IEC-T37

6-5

IEC-T37 (6-5)/0.8m/6

Dioxins

109.383 ppb (TEQ)

IEC-T37

8-7

IEC-T37 (8-7)/0.7m/2

Dioxins

3.552 ppb (TEQ)

IEC-T37

8-7

IEC-T37(8-7)/1.3m/5

Chromium

305

IEC-T37

8-7

IEC-T37(8-7)/1.3m/5

Copper

5360

IEC-T37

8-7

IEC-T37(8-7)/1.3m/5

Lead

658

IEC-T37

8-7

IEC-T37(8-7)/1.3m/5

Nickel

519

IEC-T37

8-7

IEC-T37(8-7)/1.3m/5

Zinc

1750

IEC-T37

8-7

IEC-T37(8-7)/2.8m/7

Copper

245

IEC-T37

12-11

IEC-T37(12-11)/3.4m/3

Lead

158

 

Additional Groundwater Monitoring Wells at Area 3

4.141     Sixteen (16) additional boreholes have been drilled in Area 3.  Groundwater monitoring wells were then installed at these locations.  The soil samples (taken from these boreholes) with exceedance in the relevant standards are summarised in Table 4.37.

Table 4.37     Analytical Results for Soil Samples of Additional Groundwater Wells in Area 3

 Borehole Location

Depth (m)

Contaminant

Concentration (mg/kg or otherwise specified)

AW-7

2.90-3.15

Lead

201

AW-9

1.60-1.85

Lead

200

AW-10

0.68-0.83

Antimony

59.5

AW-10

0.68-0.83

Barium

1420

AW-10

0.68-0.83

Copper

5890

AW-10

0.68-0.83

Lead

582

AW-10

0.68-0.83

Nickel

189

AW-10

0.68-0.83

Zinc

3390

AW-10

0.68-0.83

Dioxins

67.25 ppb (TEQ)

AW-10

1.41-1.66

Copper

778

AW-10

1.41-1.66

Zinc

2170

AW-10

2.88-3.13

Lead

185

AW-11

0.08-0.23

Lead

212

AW-11

0.65-0.80

Copper

1970

AW-11

0.65-0.80

Lead

357

AW-11

0.65-0.80

Nickel

124

AW-11

0.65-0.80

Zinc

868

AW-11

1.40-1.65

Copper

764

AW-11

1.40-1.65

Nickel

156

AW-11

1.40-1.65

Zinc

763

AW-14

2.85-3.10

Copper

455

AW-14

2.85-3.10

Phenol

1.3

AW-15

1.40-1.65

Lead

305

AW-16

0.05-0.23

Copper

322

AW-16

0.05-0.23

Lead

179

AW-18

0.20-0.35

TPH

10681

AW-21

0.68-0.83

Lead

189

 

4.142     The maximum and average concentrations of contaminants in Area 3 with exceedance are given in Table 4.38.

Table 4.38     Maximum and Average Concentrations of Contaminants in Area 3 with Exceedance

 

Unit

No. of Exceedances

No. of Samples Analysed

Maximum

Average (exceedances only)

Overall Average

Antimony

mg/kg

5

479

340

114

2.205

PCB

mg/kg

1

44

0.70

0.70

0.043

Arsenic

mg/kg

5

477

114

53

1.836

Barium

mg/kg

24

477

4660

1512

121.246

Bis(2-ethylhexyl)phthalate

mg/kg

1

474

563.00

563.00

1.211

Cadmium

mg/kg

9

478

118

20

0.643

TPH

mg/kg

14

390

88482

10980

428.456

Chromium

mg/kg

21

478

5390

918

54.671

Cobalt

mg/kg

12

485

328

99

7.649

Copper

mg/kg

92

478

28100

2758

537.664

Dibenz(a,h)anthracene

mg/kg

2

474

0.17

0.13

0.001

Hexachlorobenzene

mg/kg

1

474

1.00

1.00

0.002

Lead

Mg/kg

85

477

21100

1172

259.790

Molybdenum

Mg/kg

4

477

599

273

4.271

Nickel

Mg/kg

49

479

1790

419

46.734

Phenol

 

1

474

1.30

1.30

0.004

Tin

Mg/kg

17

479

3650

292

12.315

Zinc

Mg/kg

60

478

35700

3701

502.405

Dioxins

ppb (TEQ)

31

170

109.383

9.741

1.837

 

 

Overall Maximum and Average Concentrations of Contaminants

4.143     The overall maximum and average concentrations of 3 different types of contaminated soils are given in Tables 4.39 to 4.41.  The maximum and average levels of all 3 types contaminated soils are provided in Table 4.42.

Table 4.39     Maximum and Average Concentrations of Contaminants (with Exceedance) in Soil Contaminated with Organic Compounds Only

 

Unit

No. of Exceedances

Maximum

Average (exceedances only)

Benzo(a)anthracene

mg/kg

3

1.67

1.48

Benzo(a)pyrene

mg/kg

2

1.60

1.52

Benzo(b)fluoranthene

mg/kg

3

1.50

1.39

Bis(2-ethylhexyl)phthalate

mg/kg

1

46.00

46.00

TPH

mg/kg

42

25891.00

6814.38

Dibenz(a,h)anthracene

mg/kg

4

0.21

0.16

Indeno(1,2,3-cd)pyrene

mg/kg

2

1.09

1.01

Naphthalene

mg/kg

6

20.80

14.20

Styrene

mg/kg

1

6.30

6.30

 

Table 4.40     Maximum and Average Concentrations of Contaminants (with Exceedance) in Soil Contaminated with Metals Only

 

Unit

No. of Exceedance

Maximum

Average (exceedances only)

Antimony

mg/kg

5

101.00

59.56

Arsenic

mg/kg

7

114.00

48.63

Barium

mg/kg

40

4660.00

1428.20

Cadmium

mg/kg

17

18.10

8.26

Chromium

mg/kg

44

5390.00

770.73

Cobalt

mg/kg

17

328.00

91.18

Copper

mg/kg

183

28100.00

1992.45

Cyanide

mg/kg

1

123.00

123.00

Hexavalent Chromium

mg/kg

2

392.00

340.00

Lead

mg/kg

133

26300.00

1130.89

Molybdenum

mg/kg

5

599.00

227.76

Nickel

mg/kg

94

1790.00

398.55

Tin

mg/kg

25

232.00

91.12

Zinc

mg/kg

86

28900.00

3037.48

 

Table 4.41     Maximum and Average Concentrations of Contaminants (with Exceedance) in Soil Contaminated with Metals & Organic Compounds

 

Unit

No. of Exceedance

Maximum

Average (exceedances only)

Antimony

mg/kg

1

340.00

340.00

PCB

mg/kg

3

33.40

13.27

Arsenic

mg/kg

1

42.00

42.00

Barium

mg/kg

3

2220.00

1173.00

Benzo(a)anthracene

mg/kg

2

1.34

1.28

Benzo(a)pyrene

mg/kg

2

1.90

1.46

Benzo(b)fluoranthene

mg/kg

3

2.38

1.50

Bis(2-ethylhexyl)phthalate

mg/kg

1

563.00

563.00

Cadmium

mg/kg

3

118.00

43.16

TPH

mg/kg

19

88482.00

11384.68

Chromium

mg/kg

4

890.00

518.50

Cobalt

mg/kg

1

69.00

69.00

Copper

mg/kg

21

14900.00

3870.29

Dibenz(a,h)anthracene

mg/kg

5

0.66

0.25

Hexachlorobenzene

mg/kg

1

1.00

1.00

Indeno(1,2,3-cd)pyrene

mg/kg

1

1.51

1.51

Lead

mg/kg

15

21100.00

2078.00

Nickel

mg/kg

9

767.00

331.89

Phenol

mg/kg

1

1.30

1.30

Tin

mg/kg

3

3650.00

1284.36

Zinc

mg/kg

14

35700.00

4423.50

 

Table 4.42     Maximum and Average Concentrations of All Contaminants with Exceedance

 

Unit

No. of Exceedances

No. of Samples Analysed

Max.

Average (exceedances only)

Overall Average

Antimony

mg/kg

6

1910

340.00

106.30

0.709

PCB

mg/kg

3

333

33.40

13.27

0.124

Arsenic

mg/kg

8

1905

114.00

47.80

1.185

Barium

mg/kg

43

1903

4660.00

1410.40

64.174

Benzo(a)anthracene

mg/kg

5

1844

1.67

1.40

0.008

Benzo(a)pyrene

mg/kg

4

1847

1.90

1.49

0.009

Benzo(b)fluoranthene

mg/kg

6

1849

2.38

1.45

0.010

Bis(2-ethylhexyl)phthalate

mg/kg

2

1847

563.00

304.50

0.361

Cadmium

mg/kg

20

1910

118.00

13.50

0.274

TPH

mg/kg

61

1906

88482.00

8237.92

293.315

Chromium

mg/kg

48

1910

5390.00

749.71

28.034

Cobalt

mg/kg

18

1914

328.00

89.95

4.371

Copper

mg/kg

204

1910

28100.00

2185.75

241.537

Cyanide

mg/kg

1

1634

123.00

123.00

0.095

Dibenz(a,h)anthracene

mg/kg

9

1849

0.66

0.21

0.002

Hexachlorobenzene

mg/kg

1

1849

1.00

1.00

0.001

Hexavalent Chromium

mg/kg

2

1585

392.00

340.00

0.769

Indeno(1,2,3-cd)pyrene

mg/kg

3

1848

1.51

1.17

0.007

Lead

mg/kg

148

1907

26300.00

1226.88

134.691

Molybdenum

mg/kg

5

1907

599.00

227.76

1.783

Naphthalene

mg/kg

6

1848

20.80

14.20

0.053

Nickel

mg/kg

103

1910

1790.00

392.73

24.928

Phenol

 

1

1849

1.30

1.30

0.001

Styrene

mg/kg

1

1836

6.30

6.30

0.005

Tin

mg/kg

28

1906

3650.00

218.97

4.072

Zinc

mg/kg

100

1912

35700.00

3231.52

206.157

Dioxins

ppb (TEQ)

39

202

109.383

8.299

1.658

 

4.144     The laboratory results of TBT for soil samples indicate that there is no exceedance in the action level of TBT for soil remediation.

Extent of Soil Contamination

4.145     Plan views of the soil-contaminated areas at Area 1, Area 2 and Area 3 are shown in Figure 4.4, Figure 4.5 and Figure 4.6, respectively.

4.146     Contaminated areas, depths, and conservative estimated volume of soil that may exceed the cleanup targets are summarised in Table 4.43.  As the distribution of sampling locations and soil sample volumes tested are very small compared with the estimated contaminated areas and volumes of contaminated soil, the volumes shown in Table 4.43 are ‘best conservative estimates’.

Table 4.43     Contaminated Areas, Depth & Estimated Volumes of Soil Exceeding Action Levels

Area

Buildings

Contaminants

Average Depth

Maximum Depth

Soil Volume

1

B, D, I, J, L, M, N, O, and P

Metals, Petroleum Hydrocarbons (TPH), Semi-volatile Organic Compounds (SVOCs), and Dioxins

0.9m

3.1m

10,150 m3

2

R, S, T, V, W, X, Y, Z, and trenches

Metals, Petroleum Hydrocarbons (TPH), Semi-volatile Organic Compounds (SVOCs), and Dioxins

1.4m

3.4m

15,250 m3

3

Q and trenches

Metals, Petroleum Hydrocarbons (TPH), Semi-volatile Organic Compounds (SVOCs), and Dioxins

2.9m

4.5m

61,600 m3

Total =

87,000 m3

 

Volumes of Contaminated Soil

4.147     On the other hand, the volumes of different types of contaminated soil at Area 1, Area 2 and Area 3 have been estimated based on the available laboratory results and are tabulated in Table 4.44.  It should be noted that although 1 ppb TEQ is used as the action level for dioxins in soil, in order to have a safety factor for treatment of dioxin-contaminated soil, 0.1 ppb TEQ is used for estimating the volume of dioxin-containing soil that needs to be excavated for treatment.

Table 4.44     Estimated Volume of Different Types of Contaminated Soil in Areas 1, 2 and 3

Area

Metals Only

TPH/ SVOCs

Metals and TPH/ SVOCs

Dioxins and Metals/TPH/ SVOCs

1

6,000 m3

300 m3

3,800 m3

50 m3

2

7,000 m3

400 m3

4,000 m3

3,850 m3

3

35,000 m3

0 m3

500 m3

26,100 m3

Total

48,000 m3

700 m3

8,300 m3

30,000 m3

 

4.148     Note that the locations of the proposed exploratory trenches of buried waste were determined by the results of the geophysical survey.  Normally, one soil sample was collected from the apparently impacted soil and another from beneath the impacted soil per every 15 linear meters of the trench.  If presence of pollutants is confirmed in the impacted sample by laboratory results, the whole portion of the trench (15m), where the impacted soil were collected, is then classified as contaminated, and vice versa. The depth of contamination was then determined by the laboratory results of the apparently “clean” sample.  The estimation of impacted soil shown in Table 4.44 is based on this approach.

4.149     The percentages of different types of contaminated soil in Area 1, Area 2 and Area 3 have been calculated based on the estimated volumes of different types of contaminated soil, and are tabulated in Table 4.45.  Furthermore, the percentages of different types of contaminated soil in the whole CLS site are shown in Table 4.46.

Table 4.45     Estimated Percentages of Different Types of Contaminated Soil in Areas 1, 2 and 3

Contaminant(s)

Area 1

Area 2

Area 3

Metals only

59.1 %

45.9 %

56.8 %

TPH/SVOCs

3.0 %

2.6 %

0 %

Metals and TPH/SVOCs

37.4 %

26.2 %

0.8 %

Dioxins and Metals/TPH/ SVOCs

0.5 %

25.2 %

42.4 %

( Total = )

(100 %)

(100 %)

(100 %)

 

Table 4.46     Estimated Percentages of Different Types of Contaminated Soil in Whole CLS Site

Contaminant(s)

Whole CLS Site

Metals only

55.2 %

TPH/SVOCs

0.8 %

Metals and TPH/SVOCs

9.5 %

Dioxins and Metals/TPH/SVOCs

34.5 %

( Total = )

(100 %)

 

Mitigation for Land Contamination

Objectives of Remediation

4.150     The objectives of the remediation are as follows:

i)      To clean up the site to the remediation targets and within the overall development programme with cost effective and well established method;

 

ii)    To minimise the environmental impacts during the excavation, construction and operation of the remedial systems; and

 

iii)   To protect construction workers adequately from site hazards.

 

Cleanup Targets for Soil

4.151     In general, the cleanup targets for soil are also the Dutch ‘B’ Standards of the concerned contaminants.  For chemicals (except dioxins which is discussed in the following paragraphs) that are not included in the Dutch ‘B’ Standards, the USEPA federal standard’s Soil Screening Levels (SSLs) (published under Soil Screening Guidance : Technical Background Document) were used.  The SSLs for ingestion or inhalation, whichever is lower, were used.  If the chemicals are not included in the USEPA federal standard’s SSLs, then the USEPA Region IX PRGs were used as the cleanup targets.

Cleanup Target for Dioxins in Soil

4.152     The USEPA’s OSWER Directive 9200.4-26 (“Approach for Addressing Dioxin in Soil at Comprehensive Environmental Response, Compensation, and Liability Act (CERCLA) and Resource Conservation and Recovery Act (RCRA) Sites” signed 13 April 1998) states that 1 ppb TEQ is generally recommended as a cleanup standard for dioxins for residential soils at CERCLA and RCRA sites (5 to 20 ppb TEQ has been selected for industrial use scenarios).   

4.153     Treating soils to this standard would meet the Universal Treatment Standards (UTS) and would be consistent with USEPA’s OSWER Directive 9200.4-26.  In Hong Kong, the UTS standard has been applied to the acceptance criteria of metal contaminated soil treatment.  The level is also adopted as the cleanup level for dioxins in the EIA Report for Decommissioning of Kwai Chung Incinerator.

Cleanup Targets for Metals in Soil

4.154     For metal contaminants to be remediated by solidification, the Universal Treatment Standards (UTS) of U.S. Resource Conservation and Recovery Act (RCRA) wastes that contain metals (in 40 CFR 268) should be referred.  These standards were derived from the performance of the Best Demonstrated Available Technologies for treating these types of wastes.  The UTS for metals are given in Table 4.47.

Table 4.47     Universal Treatment Standards for Metals

Parameter

Universal Treatment Standard (mg/L as TCLP)

Antimony

1.15

Arsenic

5

Barium

21

Beryllium

1.22

Cadmium

0.11

Chromium (Total)

0.6

Hexavalent Chromium

Not available

Cobalt

Not available

Copper

7.8a

Lead

0.75

Mercury

0.025

Molybdenum

Not available

Nickel

11

Selenium

5.7

Silver

0.14

Thallium

0.2

Tin

Not available

Vanadium

1.6

Zinc

4.3

Cyanide (Total)

590

a           Please refer Section 4.155 for the derivation of this value.

 

4.155     It should be noted that the UTS standard for copper is unavailable.  To determine the UTS for copper, a comparison has been made between Drinking Water Standards for the USEPA and the USEPA Federal Register.  It was found that the 2 sets of standards differ by a factor of ~6 (for Chromium) to ~2950 (for Cyanide).  Using a more conservative approach, the factor of 6 is taken.  Therefore, the UTS for copper is taken to be the Drinking Water Standard value of 1.3 mg/L times a factor of 6, giving a value of 7.8 mg/L.

4.156     It should be noted that there is no UTS or USEPA Drinking Water Standard for hexavalent chromium, cobalt, molybdenum, and tin.  Therefore, cleanup targets are not established for these four metals.  Nevertheless, it is expected that the solidification process will likely isolate these metals in the same manner as the other metals present.

4.157     The cleanup targets for soil remediation for chemicals with exceedance in the relevant standards are provided in Appendix 4G.  Furthermore, the unconfined compressive strength of the solidified material shall be not less than 150 pound-force per square inch (psi).

On-site Excavation

4.158     Owing to the tight programme of the decommissioning of the subject shipyard for the development of theme park, it is anticipated that any contaminated soil found will be excavated for on-site or off-site treatment.  Delineation of soil contaminated areas (taking account of the site observations) has been carried out.  The conservative estimated soil-contaminated areas at Area 1, Area 2 and Area 3 that require to be excavated are depicted in Figure 4.7, Figure 4.8 and Figure 4.9, respectively.  After excavation, confirmation sampling and testing shall be carried out at limits of excavation to confirm that all contaminated soil has been excavated.  Soil samples shall be collected at the limits of excavation for laboratory analysis of contaminants with exceedance in action levels for soil remediation.  If laboratory results exceed the relevant standards, more soil shall be excavated (either laterally or vertically) and additional confirmation samples shall be collected and analysed until all confirmation samples are below the action levels.  A sampling plan showing the sampling locations, methodology, analysis parameters and QA/QC procedures shall be prepared by the Engineer for DEP’s approval before excavation begins.  More details about the excavation plan are provided in Sections 4.216 to 4.224.       

4.159     The recommended remediation methods require excavation of contaminated soil from the ground for ex-situ treatment or disposal.  Excavated soils will be placed in stockpiles.  Appropriate measures will be taken for the control of release of contaminants from the soil stockpiles.

Off-site Treatment

4.160     Metal-contaminated soil will be treated on site.  To Kau Wan is the site identified for off-site treatment.  The justifications for selecting To Kau Wan include its location being in the same district (Lantau Island), being comparatively far from sensitive receivers, and its availability for the next two/three years for treatment use.  It is anticipated that all other contaminated soil (including dioxin-contaminated soil) will be transported from CLS to To Kau Wan for off-site treatment.  

Evaluation of Remedial Treatment Methods

Potential Remediation Methods for Non-dioxin Contaminated Soil

4.161     Soil remediation options applicable to the subject site were addressed (the remedial options for dioxin-contaminated soil will be discussed later in this chapter), based on the following criteria:

·       Technical and cost effectiveness;

·       Technology development status;

·       Commercial availability;

·       Experience; and

·       Expertise requirement.

4.162     Common in-situ and ex-situ treatment technologies that were screened for the targeted soil contaminants (other than dioxins) are presented in Table 4.48.  The technologies are classified into biological treatment, physical/chemical treatment and removal, under in-situ and ex-situ methods.

Table 4.48     Treatment Technologies for Contaminated Soil with Metals/TPH/SVOCs

 Technology

In-situ Treatment

Ex-situ Treatment

Biological Treatment

Bioventing

Natural Attenuation

Biopile

Slurry Phase Bioreactors

Physical/Chemical Treatment

 

Soil Flushing

Solidification/stabilisation

 

Physical Separation

Soil washing

Solidification/stabilisation

Incineration

Removal

N/A

Landfill disposal / disposal of to off-site treatment facility 

4.163     A number of treatment technologies for the soil remediation are selected for detailed examination.  The applicability and limitations of the candidate treatment technologies are detailed in Table 4.49.

 


Table 4.49     Summary Listing of Selected Soil Remediation Technologies for Non-dioxin Contaminated Soil

Remediation Option

Status a

Applicability

Limitations

O & M Duration b

Biopile

Conventional

·       Applicable to soils contaminated with biodegradable organic compounds, e.g. TPH.

·       Most cost-effective for large volumes of contaminated material.

·       All materials and equipment are commercially available.

·   Substantial space required for static pile.

·   Excavation may cause release of VOCs.

·   Heavy metals are not treated.

·   Labour-intensive; require considerable maintenance.

Short to Medium

Solidification/ Stabilisation

(ex-situ)

Conventional

·       Applicable to inorganics, including heavy metals.

·   Environmental conditions may affect the long-term immobilisation of contaminants.

·   Some processes result in volume increase.

Short

Solidification/ Stabilisation

(in-situ)

Innovative

·       Applicable to inorganics, including heavy metals.

 

·   Depth of contaminants may limit some types of application processes.

·   Some processes result in volume increase.

·   Reagent delivery and effective mixing are more difficult and costly than for ex-situ applications.

·   Difficult for confirmatory sampling.

Short to medium

Landfill Disposal

Conventional

·       Applicable to all wastes that meet land disposal restriction treatment standards.

·       Best for removal and disposal of limited volumes of ‘hotspot’ materials from a vast area that may otherwise be ‘clean’.

·       Common practice for shallow, highly-contaminated soils.

·   Pretreatment is required for contaminated soil to meet landfill disposal criteria.

·   Least desirable management option.

·   Potential for long-term liabilities.

·   Long-term monitoring required.

Short

 

Incineration

Conventional

·       Applicable to halogenated and nonhalogenated organics, explosives, PCBs, and dioxins.

·       Economy of scale for large volumes.

·   Generally high costs.

·   Potential disposal problems for residual materials; residual ash may require further treatment.

·   Heavy metals can produce a bottom ash that requires stabilisation.

Short

Bioventing

Conventional

·       Applicable to TPH, non-chlorinated solvents, some pesticides, wood preservatives, & other organic chemicals.

·   The presence of the water table within several feet of the surface, saturated soil lenses, or low permeability soils reduce bioventing performance.

·   Vapours can build up in basements within the radius of influence of air injection wells.

·   Low soil moisture content may limit the effectiveness of bioventing.

·   Monitoring of off-gases at the soil surface may be required.

·       Low temperatures slow remediation.

Medium to long

Natural Attenuation

Innovative

·       Applicable to non-halogenated VOCs/SVOCs, and fuel hydrocarbons.

·   Data must be collected to determine model input parameters.

·   Highly skilled modellers are required.

·   Intermediate degradation products may be more mobile and more toxic than the original contaminant.

·   Contaminants may migrate before they are degraded.

·   The site may have to be fenced and may not be available for re-use until contaminant levels are reduced.

Long

Slurry-phase bioreactors

Innovative

·       Applicable to nonhalogenated SVOCs and VOCs.

·       Slurry-phase bioreactors are favoured over in-situ biological techniques for heterogeneous soils, low permeability soils, areas where underlying groundwater would be difficult to capture, or when faster treatment time is required.

·       Slurry-phase bioreactors containing cometabolites and specially adapted micro-organisms may be used to treat halogenated VOCs and SVOCs, pesticides, and PCBs in excavated soils and dredged sediments.

·   Excavation is required.

·   Sizing of materials prior to putting them into the reactor can be difficult and expensive; highly heterogeneous soils can create serious materials-handling problems.

·   Dewatering soil fines after treatment can be expensive.

·   An acceptable method for disposing of nonrecycled wastewater is required.

 

 

Short to medium

Soil Flushing

Innovative

 

·       Applicable to remove halogenated SVOCs, nonhalogenated SVOCs, PCBs, and explosives from in situ materials. 

·       Water soluble inorganic contaminants may also be removed using soil flushing.

·       Most applicable when contamination extends to groundwater table.

 

·   Leachate collection required.

·   Low permeability soils are difficult to treat.

·   Surfactants can adhere to soil and reduce effective soil porosity.

·   Reactions of flushing fluids with soil can reduce contaminant mobility.

·   The potential of washing the contaminant beyond the capture zone and the introduction of surfactants to the subsurface concern regulators. 

·   Flushing solution must be recovered and treated.

·   Long-term monitoring required.

Short to medium

Physical Separation

Conventional

·       Applicable to recovery of metals from soils, sediments, or slags in either of two situations.

·   Physical separation requires that the desired component be present in higher concentrations in a phase having different physical properties than the bulk material.

·   Separation methods applied to dry the material (e.g., screening) generate dust.

Short to medium

Soil Washing

Innovative

·       Applicable to SVOCs, fuels, and inorganics. 

·       The technology offers the potential for recovery of metals and can clean a wide range of organic and inorganic contaminants from coarse-grained soils.

 

·   Fine soil particles (e.g., silt, and clay) may require the addition of a polymer to remove them from the washing fluid.

·   Complex waste mixtures (e.g., metals with organics) make formulating washing fluid difficult

·   High humic content in soil may require pretreatment.

·   The aqueous stream will require treatment.

Medium

a           Conventional – technologies are in common use, and design and cost information is available.

Innovative – technologies are proven but may not be in common use; however, design and cost information is available.

b          Short – range from weeks to a few months.

Medium – range from several months to a year.

Long – take over a year.

 


Selection of Remediation Methods for Non-dioxin Contaminated Soil

4.164     In assisting the formulation of appropriate remedial measures, the Guidance Notes for Investigation and Remediation of Contaminated Sites of Petrol Filling Stations, Boatyards, and Car Repair/Dismantling Workshops published by the EPD suggest the following factors to be taken into consideration when evaluating the different available remediation methods:

i)      degree and extent of the contamination;

ii)    anticipated future use of the site;

iii)   nature of the contaminants;

iv)   soil characteristics; and

v)    time available for remediation.

4.165     Soil contaminated with metals can be remediated by either cement solidification or chemical stabilisation (e.g. with “Triple Super Phosphate” (TSP) as the stabilising agent).

Solidification with Cement

4.166     Cement solidification is an immobilisation technique applicable to the treatment of soil contaminated with heavy metals.  By mixing the contaminated soil with cement and sand, the metal contaminants in soil become physically bound within a stable mass.  The solid monolithic block is extremely resistant to the leaching of metal contaminants.

4.167     Cement-based solidification involves mixing contaminated materials with an appropriate ratio of cement, and possibly water and other additives.  The fundamental materials used to perform this technology are Portland-type cements.

4.168     Ex situ cement solidification has the advantages that it can provide better control of reagent addition and mixing, and quality control sampling is easier.

Stabilising with Triple Super Phosphate (TSP)

4.169     Stabilisation is an immobilisation technique applicable to the treatment of soils contaminated with heavy metals.  By reacting with a stabilising agent, the metal contaminants in soil will be reduced substantially in mobility and become fully or partially bound within the stabilised mass which is extremely resistant to the leaching of contaminants.

4.170     One option is to use “Triple Super Phosphate” (TSP) as stabilising agent (2-4%), the TSP stabilises metals by chemically binding them into new stable phosphate phases and other relatively insoluble phases in the soil.  The stabilising agent is typically mixed with contaminated soils using a pugmill (soil mixing equipment) or excavation equipment if the quantities are small (<2000 tons).  Metals most effectively stabilised by this treatment include lead, zinc, copper, cadmium and nickel.

4.171     Depending on chemical feed and water requirements, the volume expansion of the treated soil may range from 3 to 16 %.  The total metal concentrations in and the physical characteristics of the soil are not significantly changed by the treatment, however the stabilised insoluble metals compounds are much less likely to leach and migrate from the site.

4.172     In the US, remediated soils are often removed from the site, which could make the cement solidification procedure more costly because of the larger amount of solids (up to 30%) added to the contaminated materials.  This results in a substantial increase in the total mass of material that must be transported and disposed off-site.  Therefore, stabilisation with TSP or a similar material is commonly used in the US.

Selection between TSP Stabilisation and Cement Solidification

4.173     In general, stabilised soil (whether stabilised by TSP or other stabilising agents) are not backfilled on-site unless they are placed in a cell lined with an impermeable membrane.  There is little or no data on the very long-term stability of stabilised soil.  Thus, although test results indicate only minimal (substantially less than TCLP standards) leaching of metals from stabilised soils, there is no data for duration greater than approximately 25 years.

4.174     Owing to the concern about long-term stability of soil stabilised by TSP, it is recommended to use cement solidification rather than stabilisation with TSP for remediation of metal-contaminated soil.     

Remediation for Soil Contaminated with Metals Only

4.175     Soil that is contaminated by metals only will be excavated and then solidified by cement. 

Remediation for Soil Contaminated with TPH/SVOCs

4.176     It is proposed to adopt biopiling for the treatment of soils contaminated with TPH/SVOCs because the contaminant levels of SVOCs are below their respective Dutch ‘C’ Standards.  Furthermore, the soils contaminated with TPH and SVOCs shall co-biodegrade in a biopile without interference with each other.

4.177     The contaminated soil will be excavated, then treated by means of biopiling.

Remediation for Soil Contaminated with Metals and TPH/SVOCs

4.178     Soil contaminated with metals and TPH/SVOCs will first be biopiled and then solidified by cement.  It is because organic compounds may interfere with the process of solidification[1].  Interference with Portland cement or other cementitious materials can occur in several ways.  Oils and grease can coat the cement, preventing the reaction between water and cement.  Some organic compounds can be adsorbed on cement surfaces and severely retard cement hydration. 

4.179     Contaminated soil of this category shall be biopiled separately from those contaminated with TPH/SVOCs, which will be backfilled into the site after biopiling without solidification.

4.180     For soil contaminated with heavy metals and TPH/SVOCs, during the biopiling, the TPH/SVOCs in soils shall be treated to below the relevant cleanup targets prior to cement solidification.

Proposed Remediation Methods for Non-dioxin Contaminated Soil

4.181     The proposed remediation methods for “conventional contaminants’ at the subject shipyard are summarised in Table 4.50 whereas the proposed remediation strategy for the non-dioxin contaminated soil is presented in Figure 4.10.

Table 4.50     Proposed Remediation Methods for Different Types of Contaminated Soils+

Soil Contaminant(s)

Remediation Method

Justification

Metals

Cement solidification

·       Well developed technology

·       More cost effective that chemical stabilisation

·       Higher certainty of success

·       Simplicity in process (for limited quantity)

·       Solidified soil is acceptable to be reused as backfill 

TPH/SVOCs

Biopiling

·       Much faster that in situ treatment

·       Higher certainty of success

·       Simple operation

·       With operation experience in Hong Kong

·       Can address TPH and SVOCs

·       Cost effective

Metals and TPH/SVOCs

Biopiling followed by  cement solidification

Same as above for biopiling and cement solidification

+ Except dioxins which will be discussed later in this chapter. 

 

Justifications for Recommended Remedial Methods 

4.182     There is presence of cyanide at one location (B-B24 at Building B) at which metal contamination also occurs.  As solidification/stabilisation treatment is also suitable for cyanide-contaminated soil, the contaminated soil at this location shall be treated by solidification/stabilisation with other metal-contaminated soil. 

4.183     The average pH of the soil ranges from 6.5 to 8, which is amenable to treatment by solidification/stabilisation or biopiles.  According to the physical test results for the soil samples taken at the groundwater well locations proposed in the CAP across the CLS site (please refer Appendix 4F), the soil beneath the site is predominately sand.  Furthermore, it has been estimated based on the soil test results of a site investigation undertaken at CLS (please refer Appendix 4H) that the average clay content of the soil is only about 6-10%, which will not reduce the biological availability of the contaminants.

Treatability Tests for Biopile and Solidification/Stabilisation

4.184     It is recommended to carry out treatability tests to investigate the requirements and set design/operational parameters for the biopile and solidification/stabilisation methods.  These tests might have to be carried out as a follow-up work during the detailed design.

4.185     The objectives of the biopile treatability test are to: (i) determine if the presence of a wide variety of heavy metals at high concentrations in the soil will inhibit biodegradation process in biopile; and (ii) determine the appropriate design parameters, including necessary amendments, operating conditions, and treatment duration to optimise the full-scale biopile treatment.

4.186     The objective of the cement solidification/stabilisation treatability test is to determine the appropriate design parameters for the full-scale S/S treatment.

Potential Remedial Methods for Dioxin-contaminated Soil

4.187     This subsection describes the results of a comparative analysis of several process options for treatment of dioxin-contaminated soil that is found in Area 3 of CLS.  The options were compared based on effectiveness, implementability, and relative cost.  The purpose of this screening and evaluation process is to eliminate technologies that are not feasible or have severe limitations that might prevent achievement of the overall project objectives. Based on the results of the comparative analysis, a recommendation has been made for each technology (or process option) to be retained or eliminated from further consideration.

4.188     General response actions have been pre-screened, so that the remedial action will consist of either on-site/in situ storage/containment or excavation followed by off-site treatment.  General response actions such as No Action and Institutional Controls have not been considered in this evaluation as the program objective is to remove the dioxin-contaminated soils from CLS and subsequently either contained and treated off-site.  This section will therefore focus on identifying and screening applicable removal and treatment technologies (both short-term and long-term) for soils containing dioxins.  The criteria used in the evaluation are the following:

§                Effectiveness; and

§                Implementability. 

Effectiveness

4.189     The effectiveness of each technology/process option was assessed, taking into account the following:

§                Effectiveness of the process option in meeting project objectives.

§                Potential impacts to human health and the environment during the construction and implementation phases.

§                How proven and reliable the process is with respect to the contaminants and conditions at the site.

Implementability

4.190     Process options were evaluated against the following implementability factors:

§                Ability to obtain necessary permits and/or public acceptance.

§                Commercial availability of equipment and related support services necessary to implement the process option.

§                Ability to implement the technology in a time frame that meets the overall program requirements.

4.191     Table 4.51 presents the comparative analysis of process options for soils containing dioxins at Area 3 of the Cheoy Lee Shipyard.  The results of the screening and evaluation process for the general response actions, remedial technologies, and process options are graphically represented in Figure 4.11.

Table 4.51     Comparative Analysis of Process Options for Dioxin-contaminated Soil

Remediation Option

Effectiveness

Implementability

Relative Cost

Env. Benefits/Disbenefits

Incineration (Rotary Kiln):

High-temperature incineration option that would be capable of treating both solid and liquid feed materials. After passing through a screen to reduce the maximum particle size to two inches, the feed materials would be passed through a cylindrical, refractory-lined shell mounted on a slight incline (rotary kiln).  The kiln rotates to promote mixing and transfer of the material through the kiln. Temperatures in the kiln would reach 1,800° F. A secondary combustion chamber (called an afterburner) is designed to destroy organics in the flue gases and would operate at temperatures as high as 2,200° F. Treatment residuals requiring additional treatment or disposal include ash and possibly a liquid waste stream if a wet scrubber is used for treatment of emissions.

Rotary kiln incinerators have been used successfully in remediation of soils contaminated with a wide range of organic compounds. It is expected that this technology could meet the cleanup objectives for all organic contaminants, including dioxins.  Provides complete destruction of dioxins to required PRGs.

High metals concentrations in the soil may result in substantial accumulation of metals in the fly ash. Based on the metals concentrations in the fly ash, a secondary treatment, such as stabilisation, may be required to immobilise metals before placing treated soil in the ground.

Both mobile (transported intact) and transportable (delivered in pieces and assembled on-site) rotary kiln incinerators are available for on-site use. In addition, soils can be transported off-site for treatment at a stationary commercial incinerator.

It is likely that a trial burn and performance test would need to be conducted to verify the effectiveness of the kiln, if conducted on-site.

 

The costs for high-temperature incineration would be high when compared to other treatment technologies.

Incineration is potentially applicable to destroy dioxins concentrated in treatment residuals generated from other treatment processes such as thermal desorption or solvent extraction.

Incineration would produce significant amount of slag-like residue which is difficult to treat.  The residue thus requires final disposal to landfill.

Incineration consumes more energy than thermal desorption, thus will produce more greenhouse gases than thermal desorption.

Thermal Desorption:

Thermal desorption is a technology in which wastes are heated to temperatures between 300° F and 600° F (low temperature thermal desorption) or 600° F and 1,000° F (high temperature thermal desorption) to volatilise organic compounds. Bed temperatures and residence times cause selected contaminants to volatilise without oxidising. A carrier gas or vacuum system transports volatilised water and organic compounds to a vapour treatment system. 

Thermal desorption systems have proven to be effective for many organic contaminants, including VOCs, PAHs, PCBs, pesticides, and dioxins.

Thermal desorption alone does not reduce the toxicity or volume of contamination, but the associated vapour treatment system would, either directly (through treatment) or indirectly (through collection and off-site destruction of contamination).

Additional treatment of waste streams would be required.

Thermal desorption is a well-established technology; however, advance scheduling may be required to reserve a thermal desorption unit at the site.

A treatability test may be required to verify the design parameters for the thermal desorption system.

 

The costs for thermal desorption are moderate to high.  Residuals, including concentrated oily waste stream, water, off-gases, and treated soil, would all likely require further treatment and disposal.

Thermal desorption is potentially applicable and will be retained for further consideration.  Treatment residuals will require further treatment, such as solidification of treated soils and incineration of concentrated oily waste containing dioxins.

Ex Situ Vitrification:

In this process, excavated soil is passed through a high-temperature reactor where the materials are heated to their melting point and converted to a glass-like matrix, which can be used as non-structural fill material on-site or disposed of off-site. During the process, inorganic compounds become entrapped within the matrix and organic compounds are destroyed by oxidation.

Almost all organic compounds are destroyed during the process due to extremely high temperatures. Metals are immobilised into a compatible glass-like product.

The resulting vitrified mass effectively immobilises the entrapped compounds, including any residual contaminants not destroyed by the vitrification process.

Ex situ vitrification is a relatively complex, high-energy technology requiring a high degree of specialised skill and training. It has not been used extensively to date.

Moisture content and soil classification can affect the applicability of the technology. Limestone or soda ash is sometimes added to the feed soils.

The costs of ex situ vitrification would be high because of the high capital costs, high-energy requirements to melt the solids, and the specialised skill and training required to operate the system.

Because of the expected high cost of this option and the lack of proven experience in its implementation, it will not be retained for further consideration.

Soil Washing:

Soil washing is a physical/chemical process that reduces the volume of soil material undergoing further treatment by removing organic contaminants that adhere to organic matter and fine particles within a soil matrix. The affected soils are subjected to a multistage washing system where surfactants are used to separate the contaminants and the finer particles from the coarser soil materials. The exiting wash stream then undergoes additional treatment.

In soil washing the contaminated wash stream requiring treatment is only a small fraction of the original soil volume.

Soil washing has been proven effective for VOCs, SVOCs, and a wide range of metals. Soil washing is less effective for PCBs and limited data is available for dioxins.

The effectiveness will depend on factors such as: particle size distribution, moisture content, pH, and cation exchange capacity, among others.

The site soils in areas targeted for excavation may not contain a sufficient coarse fraction to make the application of soil washing effective.

Soil washing alone does not reduce the toxicity or volume of contamination, but the associated treatment system would, either directly (through treatment) or indirectly (through collection and off-site destruction of contamination).

Treatability studies would need to be conducted to identify the optimal washing reagents, estimate the amount of residual waste volumes to be created, and to quantify the effectiveness of the process for site contaminants.

Treatment residuals require additional treatment or disposal.

The costs associated with soil washing would be moderate to high; however, these costs may increase significantly if multiple treatments are required.

Soil washing will not be retained for further consideration due to its questionable effectiveness on dioxins.

Solvent Extraction:

Solvent extraction is a process by which contaminants are extracted from the soil using chemical solvents. The process involves contacting the solvent with the contaminated soil or sediment long enough to extract the contaminants. The solvent is then removed from the soil or sediment and the contaminants are separated from the solvent as a concentrated wastestream that typically requires further treatment and/or disposal.

 

The contaminated waste stream requiring further treatment is only a small fraction of the original soil volume.

Solvent extraction has been successfully used for PCBs and pesticides; however, little or no data are available for dioxins.  Several applications may be required to achieve cleanup goals.  Achievable removal efficiencies are not high enough to meet cleanup standards.

Effectiveness is dependent upon characteristics of the soil matrix to be treated.  Particle size is an important factor (fines are difficult to treat); therefore, a treatability study is required.

Solvent extraction alone does not reduce the toxicity or volume of contamination.  Incineration of treatment residuals would be required to permanently destroy dioxins.

Solvents used in the process can have undesirable characteristics such as strong odour and high flammability.

Treatability studies would need to be conducted to identify the optimal process configuration, to estimate the amount of residual waste volumes to be created, and to quantify the effectiveness of the process for site contaminants.

Full-scale solvent extraction process systems are not widely commercially available.  Fabrication of a properly sized system (3-400 tons/day) unit would take 1 year to complete.

Treatment residuals require additional treatment or disposal.

On-site treatment of soil may not be practical due to the length of time required for implementation, including treatability studies, and unit fabrication.

 

Due to the limited commercial use of this technology, the Penny’s Bay project would have to absorb the full capital cost of constructing a new system.  The costs associated with fabricating a full-scale unit are high.  Operational costs are expected to be moderate to high; however, these costs may increase significantly if multiple treatments or expensive solvents are required.

Solvent washing is potentially applicable for treatment of dioxins; however, due to its limited commercial availability, potential difficulty achieving cleanup goals, and concerns related to the safety of the solvents used, it will be eliminated from further consideration.

Stabilisation/Solidification:

Soil stabilisation is a technology that would immobilise contaminants in a soil matrix using chemical treatment.  Several types of stabilisation processes are available including: cement-based, pozzolanic, thermoplastic, sulphide, and organic polymerisation.

Effectiveness with site-specific organic contaminants would need to be demonstrated.  Effectiveness is proven for a wide range of inorganic constituents.

The mobility of the contaminants would be decreased, but not toxicity or volume. However, dioxins are already relatively immobile in soil, therefore, stabilisation/solidification would accomplish very little reduction in mobility.

The likelihood of contact with residual contaminants in the stabilised soil would be minimised because the treated materials would be contained in a solidified matrix.

Off-site use of stabilised soil would result in elimination of contaminated soil exceeding cleanup goals from the site, however, additional costs would be incurred due to backfill required.

Ex situ stabilisation is a commonly used technology that could be readily implemented at the site.

Treatability testing would be required to determine the types and amounts of admixtures and the effectiveness of the technology with site-specific organic and inorganic contaminants.

 

The costs for this option would be moderate compared to other treatment options.

Due to its failure to remove dioxins from soil, this process option will not be retained as a primary option to treat soil; however, it will be retained for use as a secondary treatment process for the residuals from the primary treatment process.

Chemical Dechlorination:

Chemical dechlorination is a technology in which a reagent is used to remove the chlorine atoms of chlorinated organic contaminants, transforming the contaminants into less toxic compounds.  There are three types of dechlorination processes: solvated electron technology, base-catalysed decomposition (BCD), and glycolate dehalogenation.  This process can be used to treat soil directly or to treat the concentrated oil residuals generated by other processes such as thermal desorption and solvent extraction.

Dechlorination has been proven effective for detoxification of pesticides, PCBs, and pentachlorophenol.

Dechlorination is one of the few processes other than incineration that has been successfully field tested for treating PCBs.

The BCD process has been shown to reduce dioxin concentrations to parts per trillion level.

Dechlorination is available commercially and could be implemented on-site; however, it has been used to treat small volumes of soil or concentrated oily residuals only.

Treatability studies would be required to confirm the effectiveness of the process.

Would produce treatment residuals that would require additional treatment or disposal.

On-site treatment of soil may not be practical due the current use of the property and the length of time required for implementation.

The unit cost for this technology is moderate to high.

Addition of substantial volume of a special blended oil (5:1) is needed for this process, increasing final volume of chemical waste disposal.  As such, this option is not recommended.

In Situ Thermal Treatment:

In situ thermal treatment involves the injection of heat into thermal wells to volatilise organic compounds. Soil vapour is extracted and treated.

In situ thermal treatment systems have not been used widely for contaminants with very low volatility.

Effectiveness depends on the conductive properties of the soil and the volatility of the contaminants.

Collected vapours would require additional treatment to reduce toxicity, mobility and volume.

Time to achieve project objectives likely to be much longer than off-site treatment options.

Effectiveness is marginal for removal of low-volatility contaminants from below the water  table.

There are a limited number of vendors actively promoting in situ thermal desorption technology.

Requires a large number of wells per acre. Technology may be more easily implemented at smaller sites.

The high water table at the site makes this technology difficult to implement. Pumping to lower the water table would be required.

A pilot test or treatability study would be required to determine the applicability in site soils.

 

The costs for in situ thermal desorption are moderate to high.

Treatment of saturated zone soils increases costs.

In situ thermal treatment will not be retained for further consideration due to the high water table at the site, the length of time required to achieve objectives, and the large number of wells that would be required for treatment.

In Situ Soil Vitrification:

In this process, electrodes would be placed in the ground and an electrical current would be passed through the soil. This current would heat the soil to temperatures in excess of 2,400°F. At these temperatures, the soils would begin to melt and would convert to a glass-like material upon cooling. During the process, inorganic target compounds would be effectively encapsulated and rendered immobile within this glass-like matrix, while some organic compounds would be destroyed by pyrolysis.

Tests have shown that the vitrified soils are very durable and leach-resistant.

Very effective for immobilising metals in soil.

Organics would be destroyed by pyrolysis at high temperatures; however metals remain.

The technology requires an unsaturated subsurface to make heat transfer to the soil matrix most effective.

The high water table at the site makes this technology difficult to implement.

The residual hardened material left in-place may not be acceptable for future construction activities planned at the site.

The costs of in situ vitrification would be high due to the significant electrical costs, especially in a high water table environment.

This process option will not be retained for further consideration because of the high water table at the site, the presence of metals remaining in the soils, and the geotechnical properties of the material left in place.

In-situ Capping:

A cap would be constructed of multiple layers of different materials.  The multi-layered in-situ cap is used to limit or eliminate infiltration of rainwater into the waste. 

The first step in constructing a multi-layered cap is typically relocation of waste and grading of the landfill surface. Construction of a gas vent layer may be required.  The gas vent layer allows landfill gases to be conveyed to vents that extend through the impermeable cap. Above the gas vent layer, a cushion layer would be constructed. A low permeability soil cover or a geomembrane is then constructed over the cushion layer. Above the geomembrane or soil cover, an optional drainage layer is constructed to help convey water that has infiltrated through the top soil layer away from the impermeable liner or soil cover. Above the drainage layer a vegetative and protective layer would be constructed. The top layer of the multilayer cap would be a top soil layer capable of supporting grassy vegetation.  The vegetation prevents erosion of the cap.  Additional elements of this alternative include construction of a slurry wall, installation of extraction wells, and a leachate treatment plant.

 

In-situ capping is an effective technology for preventing further migration of contaminants and direct human exposure to contamination. Because wastes would remain on-site without treatment, no reduction in toxicity, mobility, or volume of the contaminants would be achieved.

In situ capping technology is readily available and has been implemented at hundreds of contaminated sites in U.S. 

The costs for in-situ capping are moderate including construction costs of a multi-layered cap, a slurry wall, extraction wells and a treatment plant.  Long term O&M costs include maintenance and treatment plan O&M. 

The option is not recommended as this technology will limit the future landuse of the site, pose long-term liability and leaving the problem t future generation. 

Excavation and Long-term Off-site Storage in a Secured Landfill:

This alternative would include the excavation of contaminated soils at CLS and barging of the soils to a location (assumed to be TKW site) where they would be disposed of in a secure landfill. For long-term storage of the CLS soils, construction of a double lined landfill cell.  The lower liner includes a leak detection system and the upper liner includes a leachate collection system.  Each liner system would be composed of a geomembrane and/or a low permeability soil liner.  The final surface of the upper liner would be constructed (sloped) so that leachate is conveyed to the leachate collection system.

Excavation and Disposal of Soils in an On-Site Secure Landfill, is an effective technology for isolating the contaminated materials.  No reduction in toxicity, mobility, or volume would be achieved. 

Landfill construction technology are readily available and have been implemented at hundreds of contaminated sites in U.S.  There is potential for some degree of public opposition based on the fact that contaminants are not removed and treated, rather they are relocated leaving the land permanently unusable

The costs for this option would be high including capital costs for excavation of site soils, backfill of the CLS site, barging of the soils to the landfill site, and construction of a double-lined landfill cell, a multilayered cap, and a treatment plant.  Long-term O&M costs include cap maintenance and treatment plant O&M.

This option is not recommended due to the difficulty in finding a new landfill site and leaving the problem for future generation. 

Excavation and Temporary On-site Storage of Soils:

This alternative would include the excavation of contaminated soils at CLS and barging of the soils to TKW where they would be temporarily stored in sealable containers. 

Material excavated at the CLS site would be loaded into large ‘roll-off’ type containers.  These containers can be placed on a truck for transport to the barge or can be placed directly by crane onto the barge.  Similarly, the containers at the off-loading site can be placed by crane onto trucks for transport to the storage area.  For purposes of the FS report, it has been assumed that each container would be capable of holding a maximum of 23 tonnes and would have the following dimensions: 6.7m long, 2.5 m wide, and 1.5 m high.  Each container would be lined with a durable industrial coating capable of preventing leakage and reducing damage to the metal roll-off box.  In addition, the containers would require a sealable cover that would need to placed on top of the container to prevent material from escaping and water from entering.  This type of design for a container of this size would require some amount of customization.

 

Excavation and Temporary On-Site Storage of Soils could potentially effectively temporarily store soils.  Continued monitoring of the containers would be required to verify that leaks do not develop.

 

 

A large amount of customized roll-off containers would require fabrication.  This type of container could be easily fabricated.  This alternative would rely on obtaining a very large area of land to store the containers.

 

The largest component of these costs is purchase of the roll-off storage containers. The cost for the containers is expected to be high due to the customized nature of the containers.

 

This option is not recommended due to the potential secondary environmental impact arising from the storage of dioxin-contaminated soil.  In addition, this option is not acceptable because it is a temporary solution, leaving the problem for future generation.

Strategic Landfill Disposal:

This is the excavation of contaminated soil and direct disposal to landfill. 

This is the most simple and quickest way to dispose of large volume of contaminated soil. 

Similar to excavation.

To minimize the health risk and environmental impact during transportation, the excavated soil should be placed in sealable containers.      

 

The excavation cost will be moderate to high depending on the depth of excavation below the water table.  However, the disposal cost to landfill will be high.

This option is not recommended as this option will deplete the landfill space and long-term liability still exists. 

 


Selection of Remedial Method for Dioxin-contaminated Soil

4.192     The following subsections provide a comparison of the effectiveness and implementability for the identified thermal treatment options (Incineration and Thermal Desorption) including recommendations for treatment of dioxin-contaminated soil.  Non-thermal treatment technologies have not been considered further in the following subsections as they are identified as “not recommended” in Table 4.51. 

Effectiveness of Thermal Treatment Technologies

4.193     With respect to the ability to excavate the site to the cleanup objectives, both alternatives would meet the site cleanup criteria by performing confirmation sampling followed by additional excavation, as necessary. 

4.194     Regarding the two thermal treatment technologies evaluated, both incineration and thermal desorption are well-developed technologies that can meet a cleanup criterion of 1 ppb TEQ dioxins.  For incineration, treatability studies would not be necessary to verify the technology’s effectiveness.  Treatability studies would be required for thermal desorption to verify design criteria necessary to meet cleanup levels.  In addition, these studies would provide detailed information regarding the optimal combination of operating parameters necessary to achieve the cleanup standards, including operating temperature, residence time, and feed preparation.  The treatability study would provide estimates of volumes of the concentrated oily waste generated in the process and estimates of carbon usage.

4.195     For both options, feed preparation would be required to remove debris, to improve handling characteristics, to decrease soil moisture content, to break up clay clumps, and to provide a consistent feed.  Feed preparation includes such activities as screening, crushing, debris removal, addition of lime, tilling, and blending.  High moisture contents are likely to be encountered at the site due to the proximity of the water table to the excavation limits. 

4.196     Because thermal desorption does not directly destroy contaminants in the treatment process, a concentrated oily waste is generated that requires further handling, treatment, and disposal.   Incineration does not produce this process residual because contaminants are permanently destroyed (oxidised) in the combustion chamber and the afterburner.  Both systems would employ a Continuous Environmental Monitoring (CEM) to verify that the system is operated within acceptable ranges, ensuring that emissions requirements are met.

4.197     For incineration, used Personal Protective Equipment (PPE) generated by personnel performing excavation, materials handling, treatment system operation, and sampling activities and spent activated carbon can be treated in the rotary kiln.  For thermal desorption, these wastes would require classification and off-site transportation (by roll-off trucks) for appropriate disposal.

4.198     Both technologies would not effectively treat leachable metals and stabilisation would be required regardless of which thermal technology is selected.  Stabilisation is a well-developed technology that has been proven to reduce the concentrations of leachable metals in soils. The required mix design would be determined through bench- and pilot-scale treatability testing for stabilisation.

Implementability of Thermal Treatment Technologies

4.199     The thermal desorption option would require off-site incineration of the oily residue at the Chemical Waste Treatment Centre (CWTC).  Currently, CWTC is treating about 45 tonnes of chemical waste per day and it can treat an additional 10 to 15 tonnes per day provided that the waste is of compatible composition.  Based on our estimation of the quantity of oily waste generated in the process (Section 6 of this Report) and CWTC’s acceptance to the proposal, the oily residue arising from thermal desorption can be disposed of at CWTC for incineration.

4.200     Both incineration and thermal desorption could be implemented in a similar timeframe.  Thermal desorption would require treatability studies whereas incineration would not.  This would add 12 weeks to the overall thermal desorption schedule.  Shipping time, mobilisation, and set-up and shakedown would all require about the same length of time to complete (5 months).  Both technologies are commercially available and require permitting and licensing; however, the process is likely to be more time consuming and intensive for incineration than thermal desorption.

4.201     Both alternatives would provide similar levels of protection to workers, the public, and the environment.  The major implementability benefit of thermal desorption relative to incineration, is that it typically would reduce the quantity/ amount of material needs to be incinerated significantly (only around 600m3 non-aqueous dioxin condensate would require incineration as compared against 30,000m3 dioxin-contaminated soil), thus lowering the overall treatment cost and minimising the secondary environmental impacts.   

4.202     The two options also would require a very similarly sized area for staging of equipment and treated soil stockpiles.  Both would require erection of a structure to cover contaminated soils as part of feed preparation.  Both options would require the same size area for the stabilisation equipment.  In total, an area of approximately 5.2 hectares would be required for the treatment equipment in addition to the stockpile area. 

Selection of Secondary Remedial Method for Residue Arising from Primary Treatment

4.203     According to Table 4.51, incineration and chemical dechlorination (CD) is retained as an option for treatment of dioxin-containing residue generated from the primary treatment.  Incineration is recommended over chemical dechlorination for the following reasons:

§                The presence of soil debris reduces the effectiveness of BCD reagents which require a longer reaction time at higher temperatures. 

§                The relatively small amount of residue generated from primary treatment can be readily accepted by CWTC, which is designed to handle hazardous organic pollutants including PCBs and dioxins, for destruction. 

§                A separate process train is required for CD which will drastically increase the capital cost and land requirements of the decontamination system. 

§                Oily residue, which again entails additional treatment, will be produced from CD.  Such residue cannot be recovered by local recycler as it contains hazardous components and is classified as chemical waste.  Overseas experience reveals that the quantity of final residue generated after BCD treatment will be 5 times higher than the original amount.  Additional treatment of such residue is required (i.e. disposed of at CWTC). 

Proposed Remedial Method for Dioxin-contaminated Soil

4.204     Based on our analysis, thermal desorption is recommended for implementation over incineration.  Thermal desorption technology would provide a level of overall performance similar to incineration, but at a lower cost based on a cleanup level of 1 ppb TEQ dioxin.  However, thermal desorption would require treatability studies to verify design parameters before implementation and would generate a concentrated oily waste requiring disposal at CWTC.  A performance test of the residue is required to ensure CWTC’s operation and performance will not be compromised (as proposed in Section 6).  If necessary, additional stack monitoring and ambient monitoring will be carried out by operator of CWTC.   

4.205     According to “Innovative Site Remediation Technology: Thermal Desorption”, effective removal of a number of contaminants have been demonstrated by thermal desorption, including petroleum-contaminated and PCB-contaminated soil, VOCs, SVOCs, and pesticides but not effective in separating inorganics from the contaminated media (except very volatile metals such as mercury).  Therefore, further treatment of metal-contaminated soil (i.e. solidification) is required after thermal desorption. 

4.206     Thermal desorption is an innovative technology for site remediation and has been widely adopted in US sites (examples are shown in Table 4.52).  Recently, thermal desorption is being carried out in Australia and US for dioxin removal (dioxin project cases are also exemplified in Table 4.52).  

Table 4.52     Project Cases of Thermal Desorption for Dioxins and Other Contaminants

Project Site

Major Contaminants

Remediation Methods

Project Status

Re-solve, MA, US

VOCs, PCBs

Thermal desorption

Completed

Metaltec/Aerosystems, NJ, US

VOCs

Thermal desorption

Completed

Reich Farms, NJ, US

VOCs, SVOCs

Thermal desorption

Completed

American Thermostat, NJ, US

VOCs

Thermal desorption

Completed

USA Letterkenney SE Area, PA, US

VOCs

Thermal desorption

Completed

Wamchem, SC, US

BTEX, VOCs, SVOCs

Thermal desorption

Completed

Jacksonville NAS, FL, US

PAHs

Thermal desorption

Completed

Outboard Marine/Waukegan Harbour, IL, US

PCBs

Thermal desorption

Completed

Pristine, OH, US

BTEX, pesticides, herbicides, VOCs

The treatment consisted of thermal desorption of soil and base catalyzed dechlorination of the condensate.   

Completed

Sand Creek Industrial, CO, US

Pesticides, herbicides

Thermal desorption

Completed

Homebush Bay – Australia

Dioxins

The remediation process is a two-stage operation – Indirect Thermal Desorption followed by Base Catalysed Dechlorination of oily condensate. 

Phase 1 completed and Phase 2 is on-going. 

Coleman-Evans Wood Preserving Site, Whitehouse, Florida, US

Pentachlorophenol, Dioxins

Thermal desorption followed by off-site incineration of oily condensate. 

On-going

 

           

4.207     It is worth noting that thermal desorption is capable of treating organic contaminants other than dioxins, however, such technology is not recommended for the treatment of organic contaminants (i.e. TPH and SVOCs) found in Areas 1 and 2 due to the following reasons:

§                The operating and processing cost of thermal desorption is substantially higher than biopiling. 

§                The treatment capacity of thermal desorption is limited, <10 ton/hr (due to high moisture content), the handling of additional contaminated soil from Areas 1 and 2 will lengthen the whole decontamination process. 

§                The amount of oily residue generated will be significantly increased, resulting in additional transportation and treatment costs.

4.208     As such, thermal desorption is recommended be used solely for the treatment of dioxin-contaminated soil and a combination of biopile and solidification/stabilisation for other organic contaminants in Areas 1 and 2.

Summary of Comparison of Different Decontamination Options

4.209     Comparisons of the following five different decontamination options are summarised in Table 4.53.  Detailed comparisons between incineration and thermal desorption are presented in Table 4.54.  Based on the results of the comparison, the Option 3 is considered the best option for decontamination.

i)          Option 1 – Excavating all contaminated soil and taking them to Tsing Yi for incineration

 

ii)         Option 2 – Excavating all contaminated soil and treating all soil at TKW (with thermal desorption for dioxin-contaminated soil, biopile and/or solidification of non-dioxin contaminated soil)

 

iii)       Option 3 – Excavating all contaminated soil and on-site treatment for some (metal-contaminated soil) and treatment at TKW for others (thermal desorption for dioxin-contaminated soil, and biopile/solidification for non-dioxin contaminated soil)

 

iv)       Option 4 – Excavating all contaminated soil and on-site treatment for some (metal-contaminated soil) and treatment at TKW for others (incineration for dioxin-contaminated soil and biopile/solidification for non-dioxin contaminated soil)

 

v)         Option 5 – Excavating all contaminated soil and treating all soil at CLS site (with thermal desorption for dioxin-contaminated soil, biopile and/or solidification of non-dioxin contaminated soil)

 


Table 4.53     Summary of Comparison of Different Decontamination Options

 

 

Option 1

Option 2

Option 3

Option 4

Option 5

On-site vs off-site treatment

All off-site treatment - less environmentally acceptable 

All off-site treatment - less environmentally acceptable 

Majority will be treated on-site treatment – more environmentally acceptable

Majority will be treated on-site treatment – more environmentally acceptable

All on-site treatment – more environmentally acceptable 

Treatment method

CWTC is not designed for incineration of large quantity of contaminated soil.  May have air quality impact on nearby community.

Release of toxic components would not be a major concern as no direct incineration of soil would take place in thermal desorption process.  Also, the quantity of oily residue required disposal at CWTC would be insignificant. 

Release of toxic components would not be a major concern as no direct incineration of soil would take place in thermal desorption process.  Also, the quantity of oily residue required disposal at CWTC would be insignificant. 

May have air quality impact on nearby community. 

Release of toxic components would not be a major concern as no direct incineration of soil would take place in thermal desorption process.  Also, the quantity of oily residue required disposal at CWTC would be insignificant. 

Transportation Route (Land transport)

Require higher number of laden trips compared to on-site treatment. 

Require higher number of laden trips compared to on-site treatment. 

Require less laden trips compared to off-site treatment. 

Require less laden trips compared to off-site treatment. 

Does not require laden trips. 

Soil storage method

Require special storage/ handling facility due to limited capacity of CWTC.  Additional land would be required in the vicinity of CWTC.   

Land provision of storage facility would not be a constraint. 

Land provision of storage facility would not be a constraint. 

Land provision of storage facility would not be a constraint. 

Land provision of storage facility would not be a constraint. 

Final Disposal of decontaminated soil

Final disposal of ash residue generated is required.   

Treated soil would be suitable for future reuse (i.e. public filling). 

Treated soil would be suitable for future reuse (i.e. public filling). 

Final disposal of ash residue generated is required.   

Treated soil would be suitable for future reuse (i.e. public filling). 

Programme compliance

Comply with Penny’s Bay development

Comply with Penny’s Bay development

Comply with Penny’s Bay development

Comply with Penny’s Bay development

Does not comply Penny’s Bay development

 


Table 4.54     Detailed Comparison between Incineration and Thermal Desorption

 

Incineration

Thermal Desorption

1.     Overall Protection of Human Health and Environment

Incineration provides a permanent remedial solution by destroying all organic contaminants.  However, exhausts from the incinerator would be an environmental concern major concern if not controlled properly.  

Thermal desorption provides a permanent remedial solution by volatilising and removing all organic contaminants from soils without direct heating the soil.  After desorption, the volatilised air emission from the desorption process would be an environmental concern if not controlled properly. 

2.     Reduction of Mobility, Toxicity and Volume

Incineration would greatly reduce the toxicity and the volume of contaminated soil.  However, the resultant material would be slag-like and difficult to reuse. 

Thermal desorption would greatly reduce the toxicity, and the soil after treatment is suitable for public filling. 

3.     Short-term Effectiveness

Short-term health risk exists during excavation and incinerator exhausts.  Air monitoring programme is required during site activities to monitor workers’ safety and health. 

Short-term health risk exists during excavation and emissions from the desorption process.  Air monitoring programme is required during site activities to monitor workers’ safety and health. 

4.     Long-term Effectiveness

Incineration is a proven technology to destroy dioxin from the contaminated soil, and the source of contamination would be completely removed from CLS. 

Thermal desorption is an innovative technology to remove dioxin from the contaminated soil, and has recently been adopted in US and Australia to cleanup PCB- and dioxin-contaminated sites.  Similar to incineration, the source of contamination would be completely removed from CLS. 

5.     Implementability

This remedial option would involve the construction of an incinerator off-site at TKW.  Further treatment (i.e. landfilling) is required for the disposal of the residual ash. 

This remedial option would involve the construction of a desorption plant off-site at TKW.  Further treatment (i.e. incineration at CWTC) is required for the treatment residue. 

 

4.210     Both incineration and thermal desorption would completely destroy or remove source of contamination from CLS.  As compared in the above table, these 2 options perform similarly by providing a similar level of performance, except (1) final disposal of the treatment residue, and (2) cost for implementation.  Incineration would produce significant amount of slag-like residue requiring final disposal to strategic landfills, whereas the treated soil from thermal desorption would be suitable for public filling and residue of only 2% of the original quantity would require further treatment.  Overseas experience reveals that the remedial costs (including capital cost, treatment cost, operating and maintenance cost) for incineration is around 30% higher than thermal desorption while achieving similar performance.  Based on the comparison and discussion above, thermal desorption has a higher implementability in terms of finals waste handling and disposal, and is likely to be more less expensive.  As a result, direct incineration of all contaminated in the existing CWTC and setting up a new incineration plant at TKW is not recommended for the following reasons:

§                Existing CWTC has inadequate capacity for treating the dioxin-contaminated soil found in CLS. 

§                Direct incineration of such huge quantity of contaminated soil at either sites may have air quality impact on nearby community. 

§                With the existence of CWTC which is designed to treat hazardous wastes, constructing a new incineration plant at TKW for handling dioxin-contaminated soil is not cost-effective.  

Outline Process and Operation of Remediation

On-site Excavation

Excavation Plan

4.211     The excavation plans for contaminated areas at Area 1, Area 2 and Area 3 of the CLS site are shown in Figure 4.7, Figure 4.8 and Figure 4.9, respectively.  Detailed design drawings for planned excavations in the indicated areas shall be prepared by the Contractor.  Factors such as excavation areas and depths, engineering properties and stability of the soils shall be considered for safe working conditions.  The excavations shall be designed in accordance with the geotechnical properties of the soils and appropriate safety factors as determined by the Engineer.

4.212     The excavations shall also be designed considering the buried utilities lines.  A proper utility survey shall be conducted and any live utility lines shall be de-energised properly prior to excavation.

4.213     All excavation areas shall be set out by an appropriate qualified and licensed land surveyor based upon the excavation plans shown in Figures 4.7 to 4.9.

4.214     The excavation sequence would be as follows:

i)      Excavate the contaminated soil and properly packed (the package and storage requirements are dependent on the contaminants found, i.e. dioxin-contaminated soil will be placed in roll-off trucks) until no contaminants are found (confirmed by field and laboratory tests);

ii)    Soils contaminated with different types of contaminants shall not be mixed to avoid the increase the volume of soil that would require treatment by different remediation methods.

iii)   Transport dioxin-contaminated soil by roll-off trucks for off-site treatment.

iv)   Any free product encountered during excavation will be skimmed off and drummed for off-site disposal to licensed Chemical Waste Treatment Centre (CWTC).

v)    Finally, backfill the excavation with suitable materials.

 

4.215     It should be noted that for the areas to be excavated in Area 3, the upper 1m of soil within the whole areas shall be excavated first and managed as metal-contaminated soil.  Care shall be exercised to avoid mixing apparent burn/waste pit materials with soil from this upper 1m layer.

4.216     After excavation, confirmation sampling and testing shall be carried out at limits of excavation to confirm that all contaminated soil has been excavated.  Soil samples shall be collected at the limits of excavation for laboratory analysis of contaminants with exceedance in action levels for soil remediation.  Samples shall be analysed and if the analytical results are below the relevant action levels, removal of contaminated soil shall be considered complete.  If the analytical results exceed the relevant action levels, more soil shall be excavated (either laterally or vertically depending on whether the exceeding confirmation sample is collected from a sidewall or excavation base), and additional confirmation samples shall be collected and analysed until all confirmation samples are below the relevant action levels.

4.217     For small excavation areas (i.e. measure approximately 10m by 10m in size), one confirmation sample shall be collected from the base and one from each sidewall of the excavation.  The depth of sampling shall be based on the depth of the original SI sample result that triggered excavation in that area.  If SI samples from multiple depths exceeded action levels and triggered excavation, confirmation samples shall be collected for each depth where a sample exceeded these values.  Furthermore, if there are any visible indications of impact, samples shall be collected from the apparent impact zone(s).

4.218     For larger excavation areas, confirmation samples shall be collected from sidewalls of the excavation with a lateral spacing of not more than 15m.  At least one confirmation sample shall be collected from each sidewall.  Depth of sidewall samples shall be based on the depth of the original SI sample result that triggered excavation in that area.  If SI samples from multiple depths exceeded action levels and triggered excavation, confirmation samples shall be collected for each depth where a sample exceeded these values.  Confirmation samples from the base of larger excavation areas shall be collected on a grid spacing not larger than 15m by 15m (i.e. one sample per approximately every 225m2).  In all cases, if there are any visible indications of impact, samples shall be collected from the apparent impact zone(s).    

4.219     A sampling plan showing the sampling locations, methodology, analysis parameters and QA/QC procedures shall be prepared by the Engineer for DEP’s approval before excavation begins.

Precautionary Measures to Avoid Environmental Nuisance during Excavation

4.220     Spoils generated during excavation shall be placed on heavy-duty and impermeable sheeting adjacent to the excavation.  For dioxin-contaminated soils, they shall be temporarily stockpiled at such sheeting and then be placed in roll-off trucks for ex-situ treatment.  The temporary stockpiles shall be properly covered by impermeable sheeting to avoid leaching out of contaminants during wet season.

Health and Safety Plan for Excavation

4.221     As contamination with TPH has been identified at the subject site, during excavation, particular emphasis is placed on contaminated soil excavation and working in areas that may contain potentially explosive and/or toxic vapours.  The presence of explosive gas in the excavation pits shall be checked by using a Combustible Gas Indicator (CGI). 

4.222     All construction activities shall be carried out by persons appropriately trained in health and safety and appropriated personal protective equipment shall be used by the persons engaged in decontamination activities.  The following guidelines of Health and Safety shall be strictly followed by all site personnel working on the site at all times:

i)      Temporary fencing or warning ribbons will be provided to the boundary of excavation, slope crest and temporarily stockpiled areas.  Where necessary, the exposed areas will be temporarily covered with impermeable sheeting during heavy rainstorm.

 

ii)    Workers are required to wear appropriate protective clothing and safety equipment.

 

iii)   Smoking, eating and drinking are strictly prohibited.

 

iv)   Monitoring for Lower Explosive Limit in the work zone, and total VOCs (with a Photo-ionisation Detector (PID)) in the breathing zone shall be undertaken.  If the PID reading in the breathing zone is greater than 100 ppm, monitoring for benzene in the breathing zone shall also be undertaken.    

v)    Relevant occupational health and safety regulations and guidelines during excavation shall be observed.

Off-site Biopiling

4.223     Biopiling is a commonly accepted bioremediation method for the restoration of site contaminated with TPH and SVOCs.  By using micro-organisms to degrade contaminants in soil, biopiles transform hazardous/toxic materials into harmless elements such as water, carbon dioxide, and other innocuous products.  This technology offers the very important advantage of permanently removing contaminants by biodegradation, and therefore reduces potential long-term liabilities.

4.224     The biopile operates on the principle of volatilisation and biodegradation, where air is extracted from the biopile to enhance volatilisation of the hydrocarbon.  The induced airflow provides oxygen for the biodegradation processes.

Biopile Formation

4.225     The schematic of a typical single biopile is shown in Figure 4.12.  The main components in the treatment process for contaminated soil in the biopile system are:

i)      Soil

ii)    Air inlet piping

iii)   Vapour extraction pipes installed inside the biopile

iv)   Lateral offset, lateral and header pipes

v)    Biopile knockout tank and blower

vi)   Carbon adsorption system

vii)    Irrigation pipes for adding moisture and nutrients

viii)  Soil monitoring probes for in-situ measurement of soil moisture, temperature, oxygen, and carbon dioxide

4.226     The formation of a biopile will be started from one end and along the longitudinal direction.  Uniform starting concentrations will facilitate the control of the bioremediation and ensure a short cleanup time (as decontamination will not be controlled by patches of soil with high initial concentrations).  Compaction of the biopiles by excavation machinery shall be avoided in order have uniform density of the biopiles.  Bulking agents are not usually added as they are hard to be compacted during backfilling.  All biopiles shall be covered by impermeable sheeting (such that not longer than 5m of a biopile shall be exposed to open air) to avoid fugitive emissions of dust or any air pollutants from the biopiles affecting the surrounding environment.  Adequate turning will be undertaken during biopile formation (and installation of piping) to maximise sufficient air circulation.  Turning of soil may also be used during operation to enhance air circulation.  Nevertheless, this will be confirmed by the cleanup progress monitoring.

4.227     The carbon filter system shall be designed, constructed, operated and maintained to ensure adequate adsorption efficiency to prevent air pollution impact to the surrounding air sensitive receivers (ASRs).  The location of the exhaust of the carbon filter shall be sited as far away as possible from the nearby ASRs.  The carbon adsorption system shall also be monitored regularly to check the performance of the carbon filter.

4.228     The first soil samples shall be taken once the construction of a biopile is completed to serve as the baseline samples.  The baseline conditions shall be used as the reference conditions for assessing the cleanup progress of the subsequent biopile operation.

Biopile Operation

4.229     The biopile operation involves the induction of air into each biopile resulting from the establishment of a negative pressure field within each biopile.  The negative pressure encourages the “evaporation” or volatilisation of part of the hydrocarbon contamination that is adsorbed to the soil particles.  The inducted air collects the vapour and transports it via the extraction pipes out of the biopile.  The inducted air also maintains aerobic conditions in the soil pores which encourages biodegradation of the remaining non-volatile petroleum hydrocarbons.

4.230     The typical flow rate for every 1,000m3 soil is 4 scmm at the beginning and is to be decreased to 10-20% as the process progress.

4.231     As a large part of the hydrocarbon contaminant is not expected to be volatilised, cleanup of the non-volatile contaminant will depend on the biodegradation process, which produces CO2.  Thus, the gas obtained from the biopile shall comprise a mixture of air, water vapour, CO2, and vaporised hydrocarbons.  Exhaust air shall be passed through the activated carbon filters prior to discharge to the atmosphere to remove any contaminants.

4.232     Suitable conditions in the biopile shall be maintained for the growth of microbes.  Moisture will be periodically added to the soil to maintain the moisture content within 10 % to 20 %.  The optimal oxygen concentration in soil gas is 15 % to 20 %.  The soil pH shall be maintained between 5 and 8 for bacteria to survive.  Nutrients are required for microbial activities in small amounts.  Regular progress monitoring of the soil conditions will be conducted to ascertain these conditions have been maintained.  In addition, TPH levels in the soil will also be tested to assess the decontamination performance of the system.  Bacterial numbers in soil (CFU heterotrophs or CFU degraders/gram soil) is a good indicator of the health of the biopile.  This parameter shall be measured too whenever soil samples are collected for TPH analysis during progress monitoring.

4.233     Upon achieving the relevant cleanup targets, soil from the biopile will be transported to other sites and reused as filling material or transferred to other stockpiles for the treatment by solidification if metal contamination is present.

Mitigation Measures and Monitoring for Biopile Treatment

4.234     The following mitigation measures shall also be implemented by the Contractor: (i) during formation of biopiles, the biopiles shall be covered by impermeable sheeting such that not longer than 5m of the biopiles is exposed to open air in order to prevent dust emission; (ii) during operation, the biopiles shall be fully covered to control the extraction of TOC; and (iii) spent activated carbon of the carbon adsorption system shall be replaced at appropriate intervals such that the TOC emission rate from the system is acceptable.  The Contractor shall calculate and specify the “allowable” TOC emission rate of the system and propose the replacement intervals for agreement with EPD during the detailed design stage.

4.235     Gas samples at the exhaust of the carbon filter for TOC will be monitored by CEM system.  The EM&A programme shall include an event and action plan to stop the biopiling in case unacceptable air emission is detected and resumption of biopiling will only be allowed after confirmation and implementation of appropriate mitigation measures.  All these requirements shall be included in the contract clauses for remediation.

Biopile Cleanup Progress Monitoring

4.236     The objective of operation progress monitoring is twofold: i) to monitor the progress of contaminant cleanup, and ii) to ensure suitable conditions of the soil to support microbial growth.  Progress monitoring will involve periodic soil gas monitoring, soil sampling, and physical parameter monitoring.

4.237     Soil gas monitoring points are installed within the biopiles.  Sampling of oxygen, carbon dioxide, methane and VOC concentrations in the soil gas shall be conducted once every month.  Soil gas samples are taken by pulling a gas sample from the monitoring points through a vacuum pump.  In-situ measurement of soil moisture shall be included for monitoring.  Soil gas sampling after placing the system in operation can establish the effectiveness of the aeration system.

4.238     It is proposed to undertake soil sampling (with density of 15 samples per 10,000m3 soil) monthly for the analysis of pH, nutrients, and bacterial number.  Analyses for TPH and SVOCs for soil samples shall be conducted once every 3 months.  Monitoring shall continue until the cleanup targets are achieved.  Once the cleanup targets for a location have been achieved, soil sampling at that particular location may discontinue.  Progress soil monitoring results will also indicate when the biopile decontamination process may stop.

Biopile Closure Assessment

4.239     The objective of the biopile closure assessment is to collect soil samples for testing in order to ensure that the soil contaminant levels in the biopiles are below the cleanup targets for TPH and SVOCs.  Furthermore, for soil to be treated subsequently by cement solidification, the levels of the concerned metals will also be analysed to provide the baseline conditions.

4.240     Sampling frequency of one sample per 100 yard³ (76.5 m³) is an American guideline provided in the book Biopile Design, Operation, and Maintenance Handbook for Treating Hydrocarbon-Contaminated Soils (F M von Fahnestock, G B Wickramanayake, R J Kratzke, W R Major, 1998).  However, this sampling density is intended for much smaller biopiles.  No available published international reference is available for biopiles of the capacity of this project.  Current USA project experience (a biopile project in Rhode Island) shows that the sampling frequency can be reduced if progress monitoring shows that majority of soil attained the cleanup target.  As such, it is proposed to use a sampling frequency of one sample per 100m3 soil treated.  The locations of soil sampling shall be evenly distributed across the biopiles.

4.241     Access to the sampling locations shall be through opening of heat bonded cover panels.  These openings shall be closed after each access.  Extracting the soil samples shall be accomplished using a hand auger or other methods approved by the Engineer.

4.242     All soil samples shall be analysed for TPH, SVOCs and the concerned metals.  The laboratory results are considered satisfactory when the levels of TPH and SVOCs in 95% of the samples meet the cleanup targets.  This acceptability of 95% serves to allow for laboratory error for soil analysis.

4.243     In the event that more than 5% of the samples still exceed any cleanup targets, the biopile decontamination system shall have to be restarted to fully remediate the soil.  As the typical error for laboratory analysis is ±25%, the upper limits on exceedance with respect to the 5% samples should be 1.25 times the corresponding cleanup targets for the concerned contaminants.

On-site / Off-site Cement Solidification

4.244     The soil contaminated with metals only will be treated on site at CLS at a solidification plant.  The layout plan for the on-site solidification at CLS is shown in Figure 4.13.  For the soil contaminated with TPH/SVOCs and metals, following off-site biopiling at To Kau Wan site, it will be treated at To Kau Wan site at another solidification plant. 

4.245     Prior to solidification, metal-contaminated soils shall be screened to segregate soil from debris, rock fragments, and other materials and to break soil clumps into sizes to allow effective mixing with solidifying agents. 

4.246     During the cement solidification process, cement, water and other additive(s) (such as fly ash, lime, soluble silicates, and clays) are added to the contaminated soils to form solid block.  Mixing of contaminated soils and cement/water/other additive(s) will be undertaken at a solidification plant to minimise the potential for leaching during the solidification process. 

4.247     Pugmill can be used for mixing.  It is necessary to have a uniform mixture.  Thus, the materials shall be mixed until the mixture is uniform/homogeneous.  The dry materials will be firstly mixed followed by addition of water.

4.248     The total volume of the concrete blocks shall increase by up to about 10% from the original soil volume.  For easy handling, the solidified blocks shall be broken up into a number of smaller blocks after verification procedure.

4.249     Considerations for cement solidification shall include the followings[2]:

i)      Waste characteristics (e.g. metal content, physical characteristics);

ii)    Required solidified waste properties (e.g. leachability, permeability, compressive strength.);

iii)   Operational and economic factors (e.g. cost of cement and availability & cost of other additives, materials handling, volume and weight increase); and

iv)   Test methods (e.g. leachability).

 

4.250     Two useful guidelines on solidification of contaminated soils are USEPA’s Engineering Bulletin: Technology Alternatives for the Remediation of Soils Contaminated with As, Cd, Cr, Hg, and Pb (EPA/540/S-97/500, August 1997) and USEPA’s Engineering Bulletin: Solidification/Stabilisation of Organics and Inorganics (EPA/540/S-92/015, May 1993).

Leachability Test

4.251     The soil mixture in the concrete blocks will be solidified within about 1 week.  Tests for leachability shall then be carried out for every 100 m3 of the solidified soil (i.e. with sampling frequency of one sample per 100 m3 of treated material).  Each sample shall be a composite sample collected at 5 locations throughout the treated soil pile, and the same volume of sample shall be collected at each of the locations so that the composite sample is not biased.  Once the blocks have passed the test, they will be kept on site considering their stable and inert structure.  If the blocks fail the test, they will be crushed and the soils returned to the solidification process.

4.252     Toxicity Characteristics Leaching Procedure (TCLP) shall be conducted in accordance with USEPA Method 1311 for the concerned metals.

4.253     The EPD’s TCLP limits as specified in EPD’s Guidance Notes for Investigation and Remediation of Contaminated Sites of Petrol Filling Stations, Boatyards, and Car Repairing/Dismantling Workshops are standard leachability test standards.  However, this set of standards is only applicable to disposal to landfill.  For on-site reuse, these standards are not applicable.

4.254     The “Universal Treatment Standards” (UTS) shall be used for interpretation of the TCLP test results.  The UTS for the metals have been provided in Table 4.47.

4.255     Upon completion of the leachability testing and meeting the UTS and the unconfined compressive strength requirement specified below, the solidified material shall be reused on site or off site as filling material.  As the maximum grain size of filling material is 250 mm (according to general practice), the solidified soil shall be broken down to below this size before being used as filling material.  Whenever the treated soil is to be reused as filling material, the metals only solidified soil shall be put below at least 1m of clean fill.  For dioxins/metal solidified soil containing dioxins at 1 ppb TEQ, they shall be put below at least 3m of clean fill to protect human health and below at least 2m of clean fill for soil containing other chemicals to protect ecological receptors.

Unconfined Compressive Strength Test

4.256     In order to ensure the soil will be solidified in the solidification/stabilisation process, all the soil treated with solidification/stabilisation shall be tested for unconfined compressive strength.  All the treated soil shall have unconfined compressive strength of at least 150 pound-force per square inch (psi), with reference to USEPA guideline (USEPA 1986) for hazardous waste solidification requirement.

Thermal Desorption

4.257     The treatment of dioxin-contaminated soils will be carried out at TKW site and will consist the following processes:

(i)        Mobilisation and site preparation at TKW;

(ii)       Excavation of contaminated soil;

(iii)     Transportation of excavated dioxin-contaminated soil from CLS to TKW;

(iv)     On-site thermal desorption at TKW;

(v)       On-site stabilisation at TKW;

(vi)     Demobilisation of treatment plant.

 

4.258     In the thermal desorption process, dioxin shall be removed from the contaminated matrix by heating it to approximately 1000°F (or around 540°C), causing volatilisation of contaminants. In this process the contaminant molecules are not altered.  A conceptual process flow diagram is shown in Figure 4.14.

4.259     Thermal desorption treatment systems typically consist of the following components:

(i)        A material heating chamber, with a vapour collection system to collect the desorbed contaminants and water vapour.

(ii)       A condenser and separation system to convert the collected vapours to the liquid phase and separate the water from the concentrated contaminants.

(iii)     A treated soil cooling (or quench) system.

(iv)     An air treatment system to control emissions of contaminants, including particulates, from the exhaust stack.

(v)       A continuous emissions monitoring (CEM) system.

(vi)     A water treatment system to clean the condensed water prior to recycling.

 

4.260     To avoid the generation of additional dioxins, volatilisation of dioxin will be conducted by indirect heating to contaminated materials, either by heating the carrier gas stream that is passed over the contaminated soil (which desorbs contaminants into the gas), or by heating the soil using a rotary kiln or thermal screw (which desorbs contaminants from the heated soil into a carrier gas).  This indirect heat removes contaminants without incinerating them.  Process residuals produced include treated soil, treated water, contaminated treatment media and fines (e.g., baghouse filters, spent activated carbon) from air and water treatment, and a highly concentrated contaminated oily condensate stream.

4.261     The carrier gas, containing desorbed contaminants and vaporised moisture, is then collected and cooled, allowing the water vapour and contaminants to condense. Particulates are removed using conventional treatment (e.g., cyclone, baghouse fabric filters), and can be fed back into the soil influent during system operation to minimise the volume of treatment residuals generated.

4.262     Non-condensable organic vapours are removed by passing the carrier gas through vapour-phase activated carbon canisters.  The condensed water and contaminants are gravity separated following condensation.  Conventional oil/water separation techniques are used. The water would be polished using activated carbon prior to recycling.  The oily concentrated waste containing dioxins and other contaminants will be transported off site by roll-off trucks for incineration at the local chemical waste incinerator. 

Thermal Desorption Treatability Test

4.263     Thermal desorption does not perform efficiently at treating soil with high clay content and moisture content.  Soil with high moisture content consumes more fuel as water is vaporised along with the contaminants.  Tightly packed soil does not permit uniform heat contact with all contaminants.  Both will lower the performance of thermal desorption but can be overcome by adjusting the retention time and etc.  As revealed in the SI results which are summarised in Appendices 4F and 4H, thermal desorption is applicable to CLS soils as they were found to have relatively low clay content and moisture content.  Soil composition is summarised below:

§                Clay content: 6-10%

§                Moisture content: 21.4%

4.264     To verify the applicability of thermal desorption for this project, a treatability test would be required on representative site material to determine the treatment efficiency and operating parameters.  The quantity and quality of the treatment residuals produced in the process will also be estimated.  To perform the treatability test, a representative sample (approximately 200 L) would be submitted to a laboratory for treatability testing.  This process, including plan development, sample collection and analysis, treatability testing, and reporting, may take 12 weeks.

Thermal Desorption Completion Confirmation Sampling

4.265     Following thermal treatment, the treated soil would be dry and clean.  Treated material would be sampled and analysed for dioxins and other contaminants of concern including metals to confirm treatment effectiveness.  Initially, the sampling frequency shall be 1 sample per 50m3 of treated soil.  Following the establishment of acceptable system performance, we propose to collect one composite sample per day to ensure the predefined cleanup objective is achieved.  The composite is made up from samples collected every 4 hours so that the composite is representative of the entire day’s performance.  Subject to the soil feed rate, the sampling frequency shall be either one composite sample per day or 1 sample per 100m3, whichever is more frequent.  Due to the high cost of dioxin testing and long turnaround time for testing results, a cost-effective closure and programme-wise strategy should be proposed by the Contractor.  One possible option is to use on-site test equipment (i.e. bioassay) for screening the dioxin levels.  The detection limits in ppt range and quick turnaround times (i.e. less than 1 week) shall be achievable.  Treated soils containing high metals concentrations exceeding allowable limits shall be treated using solidification/stabilisation prior to backfilling at the site (please refer Sections 4.244 to 4.256 above).  Following solidification treatment, the treated material would be subject to leachability test as detailed previously in this Section to determine the suitability for reuse as backfill material.  Upon completion of treatment of all the contaminated soils, the systems would be demobilised from the site.

Engineering Design and Construction Sequence

4.266     The proposed layout of the decontamination works for dioxin treatment, biopile, solidification and area to be used for bunded storage (of dioxin-contaminated soil) at To Kau Wan site is shown in Figure 4.15 whereas sections of dioxin waste storage building are shown in Figure 4.16.  It is assumed that all the existing land at To Kau Wan will be available for decontamination.

4.267     The proposed programme for the decontamination works including excavation, biopile, solidification and dioxin treatment is shown in Figure 4.17. 

Environmental Mitigation Measures and Safety Measures

Environmental Mitigation Measures

General

4.268     Impermeable sheeting shall be put on dusty vehicle loads transported between site locations.

4.269     Speed controls for vehicles shall be imposed on dusty site areas.   

4.270     Vehicle wheel and body washing facilities at the site’s exist points shall be established and used.

Excavation

4.271     Stockpiling site(s) shall be lined with impermeable sheeting and bunded.  Stockpiles shall be fully covered by impermeable sheeting to reduce dust emission.  If this is not practicable due to frequent usage, regular watering shall be applied.  However, watering shall be avoided on stockpiles of contaminated soil to minimise contaminated runoff.

4.272     Stockpiles shall be fully covered by impermeable sheeting to minimise contaminated runoff for the stockpiles.  All leachate from the stockpiling site(s) shall be collected and treated prior to disposal.

4.273     Although it is understood that most of the contaminated soil shall be excavated during dry season as far as practicable to minimise runoff from contaminated soils, excavation and stockpiling shall be carried out during dry season as far as possible to minimise contaminated runoff from contaminated soils.

Transportation of Dioxin-contaminated Soil/Waste for Off-site Treatment (CLS to TKW)

4.274     Environmental and safety measures for transportation to minimise secondary environmental impacts and risks of transport vehicle accidents will be addressed in Chapter 6 “Waste Management Implications”. 

Biopile Formation

4.275     To avoid fugitive emissions of dust or any air pollutants from the biopiles and to minimise runoff from the stockpiled soils, the stockpiled soils at the biopiles shall be covered by impermeable sheeting such that not longer than 5m of the biopile is exposed to open air.

4.276     Upon formation of a biopile, the biopile shall be fully covered by impermeable sheeting to prevent dust emission and runoff.

4.277     Impermeable sheeting shall be placed at the bottom of the biopiles and leachate collection sump shall be constructed along the perimeter of the biopiles to prevent leachate from contaminating the underlying soil/groundwater.  The collected leachate shall be treated at the dedicated water treatment unit (with flocculation/coagulation and activated carbon filtering) at TKW.

Biopile Operation

4.278     The vented air from the biopiles shall be connected to blower and carbon adsorption system for treatment before release to the atmosphere.  Exhaust air from the blower and carbon adsorption system shall be monitored for VOCs regularly.

4.279     The biopiles shall be fully covered by impermeable sheeting to control the extraction of VOCs.

4.280     Spent activated carbon of the carbon adsorption system shall be replaced at appropriate intervals such that the VOC emission rate from the system is acceptable.

4.281     Silencers shall be installed at the biopile blowers to minimise noise impact.

4.282     Contaminated runoff from biopiles shall be prevented by constructing a concrete bund along the perimeter of the biopiles.

Thermal Desorption

4.283     To ensure no unacceptable levels of airborne contaminants are discharged, a CEM system will be installed to measure stack emission including oxygen, carbon monoxide, and total hydrocarbons.

4.284     Dioxin emissions from the stack of thermal desorption plant shall be sampled regularly in accordance with USEPA Method 23. Upon satisfactory completion of the commissioning test (including the performance and emission compliance checks) of the plant, stack sampling shall be conducted each month for the first half year and the monitoring result shall be reviewed.  Any exceedance occurs in the first half year will lead to an action of suspending the plant operation and further reviewing the plant treatment process.  If no exceedance is recorded for the first half year, the monitoring frequency will be stepped down to once every 3 months for the remainder of programme. For the in-stack continuous environmental monitoring, the action for any non-compliance of the pre-determined emission standards would be to suspend the plant operation and to review the plant process before the plant operation can be resumed 

4.285     The transportation of dioxin-contaminated soil shall be containerised to ensure no emissions will come from the dioxin waste during transportation and storage.

4.286     An emergency contingency plan for the control and mitigation measures in the event that there is any malfunction or accident in the thermal desorption plant will be prepared by the Contractor.  In addition, a hazard and operatability study (HAZOP) shall be carried out by the Contractor to identify any hazards associated with the operation of the thermal desorption process so as to incorporate appropriate safety devices during the design of the thermal desorption plant.  The HAZOP Report shall be submitted to the Engineer for his approval prior to the operation of the thermal desorption plant.  

4.287     A designated pit/ shed shall be provided for decontamination of trucks or equipment in contact with the dioxin waste to avoid cross-contamination. 

4.288     The by-products generated from the process shall be handled in strict accordance with the Waste Disposal Ordinance and Waste Disposal (Chemical Waste) (General) Regulation. 

4.289     To minimise the waste generation and requirements for off-site disposal, the condensate shall be separated into aqueous and non-aqueous phases.  The aqueous condensate shall be polished on site for recycling to quench and rehydrate the treated soils which are hot and powdery, whereas the non-aqueous condensate shall be drummed properly for off-site disposal at Chemical Waste Treatment Centre (CWTC).  The details of the waste management of the non-aqueous condensate are presented in Chapter 6 “Waste Management Implications”.   

General Health and Safety Measures

4.290     The relevant requirements under the Occupational Safety and Health Ordinance (OSHO) (Chapter 509) and their subsidiary Regulations shall be strictly followed throughout the Project.  Only experienced personnel will be employed to operate the thermal desorption plant.  During the course of the site remediation, the following basic health and safety measures shall be implemented:

i)          Set up a list of safety measures for site workers;

ii)         Provide written information and training on safety for site workers;

iii)       Keep a log-book and plan showing the contaminated zones and clean zones;

iv)       Maintain a hygienic working environment;

v)         Prohibit eating and cooking inside the contaminated zones;

vi)       Avoid dust generation;

vii)      Provide face and respiratory protection gear to site workers;

viii)    Provide personal protective clothing (e.g. chemical resistant jackboot, liquid tight gloves) to site workers; and

ix)        Provide first aid training and materials to site workers.

 

Personal Protective Equipment for Workers during Excavation of Dioxin-contaminated Soil

4.291     Site workers for excavation of dioxin-contaminated soil will be exposed to dioxin-contaminated dust during excavation.  To determine whether a higher level of protection is required, a past American Industrial Hygiene Association study is referred.  It suggests an Occupational Exposure Limit (OEL) of 0.2ng/m3 (note that this value is based upon a 100-fold safety factor from animal data and base dupon exposure to “pure” dioxin).  Using this standard, and the 99th percentile concentration of 23.5 ppb TEQ in soil, a total dust reading in air of 8.51mg/m3 before the dioxin exposure standard of 0.2ng/m3 is reached has been calculated.  Dioxin is not volatile and would be present in the air only in the particulate form; therefore, a NIOSH-approved respirator with a HEPA filter would be adequate to protect the site workers from dioxin-contaminated dust exposure.  It is suggested to implement Level C (air purifying respirator) protection at 2.5mg/m3 for nuisance dust purposes.  With such level of protection, the site personnel will be protected at levels well below 0.2ng/m3.

4.292     The workers engaged in the excavation of dioxin-contaminated soil shall put on appropriate PPE to minimise the exposure to the carcinogens via inhalation, ingestion and dermal contact:

§                An air purifying respirator;

§                Latex gloves;

§                Protective clothing. 

4.293     Concentration of 109.383 ppb TEQ dioxins has been measured at trench T37 for burn pit in Area 3.  It is proposed that additional PPE such as powered air purifying respirator should be provided for site workers, under supervision on site.

4.294     According to our above assessment, a higher level of protection, such as self-supplied respirators, space suit, is not required.  However, if other contaminants are identified or the levels of contaminant are expected to be very high, a higher level of protection, such as self-supplied respirators, space suit, may be required.

Safety Measures for Handling Dioxin-containing Residue

4.295     Though the composition of the oily residue generated from thermal desorption cannot be determined at this stage, it is expected that such residue will contain mainly 1) TPH/SVOCs and 2) TPH which are dominantly found in Area 3.  According to the SI results of Area 3 presented earlier in this section, among those contaminants, TPH (particularly the heavy fractions C27-C36 which accounts for 50%) has the highest concentrations (>80,000ppm).  Therefore, TPH (the fractions resemble diesel) will be the major component of the oily residue.  In relation to the predicted composition, the oily residue shall be classified as Dangerous Goods (Cat.5, C3 which is applicable to diesel oils, furnace oils and other fuel oils) in accordance with Dangerous Goods (Classification) Regulations.  The Contractor shall observe such ordinance during storage and conveyance of the residue. 

Environmental Monitoring and Audit Requirements

4.296     The environmental monitoring and audit requirements for are those mentioned in the following sections:

i)          Section 4.96 (Free product skimming);

ii)         Section 4.97 (Groundwater recharge);

iii)       Section 4.158 and Sections 4.221 - 4.223 (Confirmation sampling for excavation of contaminated soils);

iv)       Sections 4.244 – 4.248 (Confirmation sampling for biopile treatment);

v)         Sections 4.256 – 4.261 (Confirmation sampling for solidification treatment); and

vi)       Section 4.270 (Confirmation sampling for thermal desorption treatment)

 

The details of the requirements are provided in Chapter 11 “Environmental Monitoring and Audit Requirements”.     

Conclusions and Recommendations

4.297     Soil contamination is found at Area 1, Area 2 and Area 3 of the CLS site.  Soil contamination has been found down to 3m below the existing ground level.  The contaminants at Area 1 and Area 2 include metals, total petroleum hydrocarbons (TPH), semi-volatile organic compounds (SVOCs), and dioxins.  The estimated volumes of soil contaminated with metals only in Area 1 and Area 2 are 6,000m3 and 7,000m3 respectively.  The estimated volumes of soil contaminated with metals/TPH/SVOCs in these two areas are 3,800m3 and 4,000m3 respectively.  The estimated volumes of soil contaminated with dioxins/metals/TPH/SVOCs in these two areas are 50m3 and 3,850m3 respectively.  The combined estimated volume of soil contaminated with TPH/SVOCs in these two areas is only about 700m3. 

4.298     The contaminants found at Area 3 include dioxins, metals, TPH and SVOCs.  The estimated volumes of soil contaminated with metals only, metals/TPH/SVOCs and dioxins/ metals/TPH/SVOCs are 35,000m3, 500m3 and 26,100m3 respectively.

4.299     For the whole CLS site, the estimated soil volumes by the soil contaminant type(s) are as follows:

Metals only : 48,000m3

TPH and/or SVOCs : 700m3

Metals and TPH and/or SVOCs : 8,300m3

Dioxins, Metals, and TPH and/or SVOCs : 30,000m3

Total estimated volume : 87,000m3

 

4.300     The environmental impacts of land contamination and land decontamination works are considered small or can be mitigated to an extent where the impacts on the receivers are acceptable.  An EM&A programme will be required for land contamination and such programme is addressed in Chapter 11 “Environmental Monitoring and Audit”.

4.301     For Area 1 and Area 2, cement solidification is recommended as the remedial treatment for soil contaminated with metals only.  Biopile followed by cement solidification is recommended for soil contaminated with metals/TPH/SVOCs.  The soil contaminated with TPH/SVOCs only shall be treated in the same biopile for the soil contaminated with metals/TPH/SVOCs.  It is recommended to treat the soil contaminated with dioxins and metals/TPH/SVOCs in these two areas using thermal desorption followed by solidification if necessary.

4.302     For Area 3, it is recommended to treat the soil contaminated with dioxins/metals/TPH/SVOCs using thermal desorption followed by cement solidification.  The soil contaminated with metals only in this area is recommended be treated using cement solidification.

4.303     The recommended decontamination option is on-site treatment for some (metal-contaminated soil) and off-site treatment at TKW for others (thermal desorption for dioxin-contaminated soil, and biopile/solidification for non-dioxin contaminated soil).  

4.304     Environmental mitigation measures for the decontamination, including excavation, transportation of dioxin-contaminated soil/waste for off-site treatment, biopile formation, biopile operation, cement solidification and thermal desorption, have been recommended.

4.305     There shall be no residual impacts after implementation of the recommended mitigation measures (i.e. decontamination) for contaminated soil.

4.306     It is recommended to conduct treatability tests for biopile and cement solidification to investigate the requirements and set design/operational parameters for the biopile and cement solidification processes.

4.307     Furthermore, it is recommended to conduct a treatability test of thermal desorption for dioxin-contaminated soil to determine the treatment efficiency, operating parameters, and the quantity/quality of the treatment residuals produced in the process.

4.308     The IEC, through their own assessment, conclude that the remedial approaches recommended in this report can effectively meet the remedial action objectives and goals for the CLS site.  The IEC also concur with this report’s selected remedy of excavation and treatment of metals-impacted soils by cement stabilisation, TPH and SVOC-impacted soils by biopiling, and thermal treatment of dioxin-impacted soils by thermal desorption.

 



[1]        Suthersan, S. S. (1997).  Remediation Engineering Design Concepts.  Lewis Publishers, New York. p.305

[2]        WASTECH (1997).  Innovative Site Remediation Technology: Stabilisation/Solidification.  American Academy of Environmental Engineers, U.S.