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Environmental Science and Pollution Research

, Volume 25, Issue 31, pp 30880–30893 | Cite as

Environmental hazards associated with open-beach breaking of end-of-life ships: a review

  • Suman Barua
  • Ismail M. M. Rahman
  • Mohammad Mosharraf Hossain
  • Zinnat A. Begum
  • Iftakharul Alam
  • Hikaru Sawai
  • Teruya Maki
  • Hiroshi Hasegawa
Review Article
  • 262 Downloads

Abstract

End-of-life (EOL) ships contribute significantly to the flow of recycled industrial Fe and non-Fe metal materials in resource-poor developing countries. The ship scrapping (breaking) and recycling industry (SBRI) recycles 90–95% of the total weight of EOL ships and is currently concentrated in Bangladesh, India, Pakistan, Turkey, and China, due to the high demand for recyclable and reusable materials there, an abundance of low-cost labor, and lenient environmental regulations. However, the SBRI has long been criticized for non-compliance with standards relating to occupational health, labor safety, and to the management of hazardous materials. Among the different EOL recycling options, Bangladesh, India, and Pakistan use open beaching, a technique that exposes all spheres of the environment to the release of hazardous materials from EOL ships. This article summarizes the current state of knowledge on the environmental exposure of hazardous materials from SBRI, to judge the risks associated with the dismantling of EOL ships on open beaches. Our work includes an overview of the industry and its recent growth, compares available ship-breaking methods, provides an inventory of hazardous releases from EOL ships, and reviews their movement into different spheres of the environment. The economic dynamics behind open beaching, and apportionment of responsibility for hazards related to it, are discussed, in order to generate policy and legal recommendations to mitigate the environmental harm stemming from this industry.

Keywords

End-of-life ships Ship-breaking Open beach Pollutants Legislation 

Notes

Funding information

This research was partially supported by Grants-in-Aid for Scientific Research (15H05118 and 17K00622) from the Japan Society for the Promotion of Science.

References

  1. Abdullah HM, Mahboob MG, Banu MR, Seker DZ (2013) Monitoring the drastic growth of ship breaking yards in Sitakunda: a threat to the coastal environment of Bangladesh. Environ Monit Assess 185:3839–3851CrossRefGoogle Scholar
  2. Ahammad H, Sujauddin M (2017) Contributions of ship recycling in Bangladesh: an economic assessment. IMO-NORAD SENSREC Project, International Maritime Organization, LondonGoogle Scholar
  3. Ahluwalia RS, Sibal P, Govindarajulu S (2004) Comparison of ship dismantling processes in India and the U.S. In: Proc. SPIE 5263, Intelligent Manufacturing, 106. pp 106–112Google Scholar
  4. Aktaruzzaman M, Chowdhury MAZ, Fardous Z, Alam MK, Hossain MS, Fakhruddin ANM (2014) Ecological risk posed by heavy metals contamination of ship breaking yards in Bangladesh. Int J Environ Res 8:469–478Google Scholar
  5. Alam S, Faruque A (2014) Legal regulation of the shipbreaking industry in Bangladesh: the international regulatory framework and domestic implementation challenges. Mar Policy 47:46–56CrossRefGoogle Scholar
  6. Alcaidea JI, Piniella F, Rodriguez-Diaza E (2016) The “Mirror Flags”: ship registration in globalised ship breaking industry. Transport Res d-Tr E 48:378–392CrossRefGoogle Scholar
  7. Andersen AB (2001) Worker safety in the ship-breaking industries. International Labour Office, GenevaGoogle Scholar
  8. Basha S, Gaur PM, Thorat RB, Trivedi RH, Mukhopadhyay SK, Anand N, Desai SH, Mody KH, Jha B (2007) Heavy metal content of suspended particulate matter at world’s largest ship-breaking yard, Alang-Sosiya, India. Water Air Soil Poll 178:373–384CrossRefGoogle Scholar
  9. Bhattacharjee S (2009) From Hong Kong to Basel: international environmental regulation of ship-recycling takes one step forward and two steps back. Trade Law Dev 1:193–230Google Scholar
  10. Browne MA, Dissanayake A, Galloway TS, Lowe DM, Thompson RC (2008) Ingested microscopic plastic translocates to the circulatory system of the mussel, Mytilus edulis (L.). Environ Sci Technol 42:5026–5031CrossRefGoogle Scholar
  11. Carvalho IS, Antão P, Soares CG (2011) Modelling of environmental impacts of ship dismantling. Ships Offshore Struc 6:161–173CrossRefGoogle Scholar
  12. Celik M, Kandakoglu A (2012) Maritime policy development against ship flagging out dilemma using a fuzzy quantified SWOT analysis. Marit Policy Manag 39:401–421CrossRefGoogle Scholar
  13. Chang Y-C, Wang N, Durak OS (2010) Ship recycling and marine pollution. Mar Pollut Bull 60:1390–1396CrossRefGoogle Scholar
  14. Choi J-K, Kelley D, Murphy S, Thangamani D (2016) Economic and environmental perspectives of end-of-life ship management. Resour Conserv Recycl 107:82–91CrossRefGoogle Scholar
  15. Chowdhury M (2016) Bangladesh ship-breakers contend no need for environmental clearance (URL: http://bdnews24.com/bangladesh/2016/11/07/no-need-to-environmental-clearance-say-ship-breakers-in-bangladesh). Accessed on 1 June 2017
  16. Claessens M, Meester SD, Landuyt LV, Clerck KD, Janssen CR (2011) Occurrence and distribution of microplastics in marine sediments along the Belgian coast. Mar Pollut Bull 62:2199–2204CrossRefGoogle Scholar
  17. ClassNK (2016) Guiding a greener industry - Classnk is supporting the improvement of ship recycling standards (URL: https://www.classnk.or.jp/hp/pdf/publications/Publications_image/classnk_magazine_no77.pdf). ClassNK Magazine (77th Edition). JLA media, Tokyo, Japan
  18. Council of the European Union (2013) Regulation (EU) No 1257/2013 on ship recycling (URL: http://data.europa.eu/eli/reg/2013/1257/oj; Last accessed on June 14, 2017). Official Journal of the European Union
  19. Demaria F (2010) Shipbreaking at Alang–Sosiya (India): an ecological distribution conflict. Ecol Econ 70:250–260CrossRefGoogle Scholar
  20. Derraik JGB (2002) The pollution of the marine environment by plastic debris: a review. Mar Pollut Bull 44:842–852CrossRefGoogle Scholar
  21. Deshpande PC, Tilwankar AK, Asolekar SR (2012) A novel approach to estimating potential maximum heavy metal exposure to ship recycling yard workers in Alang, India. Sci Total Environ 438:304–311CrossRefGoogle Scholar
  22. Devault DA, Beilvert B, Winterton P (2016) Ship breaking or scuttling? A review of environmental, economic and forensic issues for decision support. Environ Sci Pollut Res 24:25741–25774CrossRefGoogle Scholar
  23. Dimakopoulos S (2005) The IMO’s work on ship recycling. Paper presented at the International Conference on Recycling of Ships & other Marine Structures, London, May 4–5Google Scholar
  24. Dnt Norske Veritas (2000) Decommissioning of ships–environmental standards: ship-breaking practicies/on-site assessment Bangladesh – Chittagong. vol DNV RN 590 Dnt Norske Veritas, NorwayGoogle Scholar
  25. EC (2004) Oil tanker phase out and the ship scrapping industry (P-59106-07). European Commission (Directorate-General Energy and Transport), BrusselsGoogle Scholar
  26. EC (2007) Ship dismantling and precleaning of ships. European Commission (Directorate-General Environment), BrusselsGoogle Scholar
  27. Endo S, Takizawa R, Okuda K, Takada H, Chiba K, Kanehiro H, Ogi H, Yamashita R, Date T (2005) Concentration of polychlorinated biphenyls (PCBs) in beached resin pellets: variability among individual particles and regional differences. Mar Pollut Bull 50:1103–1114CrossRefGoogle Scholar
  28. Environment Australia (1999) Emission estimation technique manual for shipbuilding repair and maintenance. Environment Australia, CanberraGoogle Scholar
  29. Frey RS (2015) Breaking ships in the world-system: an analysis of two ship breaking capitals, Alang-Sosiya, India and Chittagong, Bangladesh. J World-Sys Res 21:25–49CrossRefGoogle Scholar
  30. Garmer K, Sjöström H, Hiremath AM, Tilwankar AK, Kinigalakis G, Asolekar SR (2015) Development and validation of three-step risk assessment method for ship recycling sector. Safety Sci 76:175–189CrossRefGoogle Scholar
  31. Germanischer Lloyd Aktiengesellschaft (2003) Rules for classification and construction: special materials for naval ships. Germanischer Lloyd Aktiengesellschaft, HamburgGoogle Scholar
  32. Goodwin P (2005) The ships of Trafalgar : the British, French and Spanish fleets, October 1805. Naval Institute Press, AnnapolisGoogle Scholar
  33. Gouin T, Roche N, Lohmann R, Hodges G (2011) A thermodynamic approach for assessing the environmental exposure of chemicals absorbed to microplastic. Environ Sci Technol 45:1466–1472CrossRefGoogle Scholar
  34. Government of Bangladesh (2018) Bangladesh ship recycling act (URL: http://bdlaws.minlaw.gov.bd/bangla_all_sections.php?id=1229; Last accessed on 29 Aug 2018). Ministry of law, Justice and Parliamentary Affairs, Dhaka
  35. Graham ER, Thompson JT (2009) Deposit-and suspension-feeding sea cucumbers (Echinodermata) ingest plastic fragments. J Exp Mar Biol Ecol 368:22–29CrossRefGoogle Scholar
  36. Greenpeace International (2005) End of life: the human cost of breaking ships. Greenpeace International and International Federation for Human Rights, Amsterdam / ParisGoogle Scholar
  37. Gregson N, Crang M, Ahamed FU, Akter N, Ferdous R, Foisal S, Hudson R (2012) Territorial agglomeration and industrial symbiosis: Sitakunda-Bhatiary, Bangladesh, as a secondary processing complex. Econ Geogr 88:37–58CrossRefGoogle Scholar
  38. Hahladakis JN, Stylianos M, Gidarakos E (2013) Assessment of released heavy metals from electrical and electronic equipment (EEE) existing in shipwrecks through laboratory-scale simulation reactor. J Hazard Mater 250–251:256–264CrossRefGoogle Scholar
  39. Hasan AB, Kabir S, Reza AHMS, Zaman MN, Ahsan A, Rashid M (2013a) Enrichment factor and geo-accumulation index of trace metals in sediments of the ship breaking area of Sitakund Upazilla (Bhatiary-Kumira), Chittagong, Bangladesh. J Geochem Explor 125:130–137CrossRefGoogle Scholar
  40. Hasan AB, Kabir S, Reza AHMS, Zaman MN, Ahsan MA, Akbor MA, Rashid MM (2013b) Trace metals pollution in seawater and groundwater in the ship breaking area of Sitakund Upazilla, Chittagong, Bangladesh. Mar Pollut Bull 71:317–324CrossRefGoogle Scholar
  41. Hayman B, Dogliani M, Kvale I, Fet AM (2000) Technologies for reduced environmental impact from ships-ship building, maintenance and dismantling aspects. Paper presented at the ENSUS-2000 (International Conference on Marine Science and Technology for Environmental Sustainability), University of Newcastle upon Tyne, September 4-6Google Scholar
  42. Heidegger P (2015) Dirty and dangerous shipbreaking. International Institute of Marine Surveying. http://www.iims.org.uk/dirty-and-dangerous-shipbreaking/. Accessed 7 Feb 2017
  43. Hiremath AM, Tilwankar AK, Asolekar SR (2015) Significant steps in ship recycling vis-a-vis wastes generated in a cluster of yards in Alang: a case study. J Clean Prod 87:520–532CrossRefGoogle Scholar
  44. Hiremath AM, Pandey SK, Asolekar SR (2016) Development of ship-specific recycling plan to improve health safety and environment in ship recycling yards. J Clean Prod 116:279–298CrossRefGoogle Scholar
  45. Horn GE, Marshall G, Rynn PG, Stanton ME (2008) Tanker safety: regulatory change. WMU J Marit Affairs 7:317–351CrossRefGoogle Scholar
  46. Hossain MS (2001) Biological aspects of the coastal and marine environment of Bangladesh. Ocean Coast Manage 44:261–282CrossRefGoogle Scholar
  47. Hossain KA (2015) Overview of ship recycling industry of Bangladesh. J Environ Anal Toxicol 5:312CrossRefGoogle Scholar
  48. Hossain MM, Islam MM (2006) Ship breaking activities and its impact on the coastal zone of Chittagong, Bangladesh: towards sustainable management. Young Power in Social Action, ChittagongGoogle Scholar
  49. Hossain MMM, Islam MM (2010) Ship-breaking activities: threat to coastal environment, biodiversity and fisherman Community in Chittagong. Young Power in Social Action, BangladeshGoogle Scholar
  50. Hossain MS, Chowdhury SR, Jabbar SA, Saifullah S, Rahman MA (2008) Occupational health hazards of ship scrapping workers at Chittagong coastal zone, Bangladesh. Chiang Mai J Sci 35:370–381Google Scholar
  51. Hossain MS, Fakhruddin ANM, Chowdhury MAZ, Gan SH (2016) Impact of ship-breaking activities on the coastal environment of Bangladesh and a management system for its sustainability. Environ Sci Pol 60:84–94CrossRefGoogle Scholar
  52. ILO (2004) Safety and health in shipbreaking: guidelines for Asian countries and Turkey. International Labour Office, GenevaGoogle Scholar
  53. ILPI (2016) Shipbreaking practices in Bangladesh, India and Pakistan. International Law and Policy Institute, OsloGoogle Scholar
  54. IMO (2004) IMO guidelines on ship recycling. Vol ASSEMBLY, 23rd session, agenda item 19 International Maritime Organization, LondonGoogle Scholar
  55. IMO (2007) Information Resources on Recycling of Ships. 13 December 2007 edn. International Maritime Organization, LondonGoogle Scholar
  56. IMO (2009) Hong Kong international convention for the safe and environmentally sound recycling of ships. International Maritime Organization, LondonGoogle Scholar
  57. IMO (2014) Implications of the United Nations convention on the law of the sea for the International Maritime Organization. International Maritime Organization, LondonGoogle Scholar
  58. Iqbal KMJ, Heidegger P (2013) Pakistan shipbreaking outlook: the way forward for a green ship recycling industry – environmental, health and safety conditions. Sustainable Development Policy Institute and NGO Shipbreaking Platform, Brussels / IslamabadGoogle Scholar
  59. Islam KL, Hossain MM (1986) Effect of ship scrapping activities on the soil and sea environment in the coastal area of Chittagong, Bangladesh. Mar Pollut Bull 17:462–463CrossRefGoogle Scholar
  60. Kanthak J, Jayaraman N (2001) Ships for scrap III - steel and toxic wastes for Asia. Greenpeace International, HamburgGoogle Scholar
  61. Karydis M, Kitsiou D (2013) Marine water quality monitoring: a review. Mar Pollut Bull 77:23–36CrossRefGoogle Scholar
  62. Khan MAA, Khan YSA (2003) Trace metals in littoral sediments from the north east coast of the Bay of Bengal along the ship breaking area, Chittagong, Bangladesh. J Biol Sci 3:1050–1057CrossRefGoogle Scholar
  63. Kibria G, Hossain MM, Mallick D, Lau TC, Wu R (2016) Trace/heavy metal pollution monitoring in estuary and coastal area of Bay of Bengal, Bangladesh and implicated impacts. Mar Pollut Bull 105:393–402CrossRefGoogle Scholar
  64. Knapp S, Kumar SN, Remijn AB (2008) Econometric analysis of the ship demolition market. Mar Policy 32:1023–1036CrossRefGoogle Scholar
  65. Lloyd's Register (2011) Ship recycling: practice and regulation today. Lloyd’s Register, LondonGoogle Scholar
  66. Lloyd's Register (2013) Asbestos on ships - how to manage it safely. Lloyd’s Register, LondonGoogle Scholar
  67. Lloyd's Register (2014) A guide to the inventory of hazardous materials. Lloyd's Register, LondonGoogle Scholar
  68. Long ER, Macdonald DD, Smith SL, Calder FD (1995) Incidence of adverse biological effects within ranges of chemical concentrations in marine and estuarine sediments. Environ Manag 19:81–97CrossRefGoogle Scholar
  69. Martin D, Chakraborty LB, Sinha S, Hossain MM, Saha R, Khetriwal DS, Asolekar S (2016) Safe and environmentally sound ship recycling in Bangladesh (Hazardous waste assessment report: Baseline, methodology and inventory). Secretariat of the Basel, Rotterdam and Stockholm Conventions, United Nations Environment Programme, GenevaGoogle Scholar
  70. Mikelis N (2006) Developments and issues on recycling of ships. Paper presented at the East Asian Sea Congress, Hainan, China, December 12–16Google Scholar
  71. Mikelis NE (2008) A statistical overview of ship recycling. WMU J Marit Affairs 7:227–239CrossRefGoogle Scholar
  72. Mikelis N (2013) Ship recycling markets and the impact of the hong kong convention. Paper presented at the International Conference on Ship Recycling, Malmö, Sweden, April 8–9Google Scholar
  73. Ministry of Shipping (2016) Shipbreaking code. (Revision). Ministry of Shipping, Government of India, New Delhi, p 2013Google Scholar
  74. Moen AE (2008) Breaking Basel: the elements of the Basel Convention and its application to toxic ships. Mar Policy 32:1053–1062CrossRefGoogle Scholar
  75. MoInd (2011) Ship breaking and recycling rules. Ministry of Industries-Government of the People’s Republic of Bangladesh, DhakaGoogle Scholar
  76. Mostofa KMG, Liu C-Q, Vione D, Gao K, Ogawa H (2013) Sources, factors, mechanisms and possible solutions to pollutants in marine ecosystems. Environ Pollut 182:461–478CrossRefGoogle Scholar
  77. Neser G, Unsalan D, Tekogul N, Stuer-Lauridsen F (2008) The shipbreaking industry in Turkey: environmental, safety and health issues. J Clean Prod 16:350–358CrossRefGoogle Scholar
  78. Neşer G, Kontas A, Ünsalan D, Uluturhan E, Altay O, Darilmaz E, Küçüksezgin F, Tekoĝul N, Yercan F (2012) Heavy metals contamination levels at the Coast of Aliaga (Turkey) ship recycling zone. Mar Pollut Bull 64:882–887CrossRefGoogle Scholar
  79. Ng K, Obbard J (2006) Prevalence of microplastics in Singapore’s coastal marine environment. Mar Pollut Bull 52:761–767CrossRefGoogle Scholar
  80. NGO Shipbreaking Platform (2012) Why ships are toxic. NGO Shipbreaking Platform, BrusselsGoogle Scholar
  81. NGO Shipbreaking Platform (2017a) 2016 list of all ships scrapped worldwide - facts and figures. NGO Shipbreaking Platform, BrusselsGoogle Scholar
  82. NGO Shipbreaking Platform (2017b) Substandard shipbreaking: a global challenge. NGO Shipbreaking Platform, BrusselsGoogle Scholar
  83. Nøst TH, Halse AK, Randall S, Borgen AR, Schlabach M, Paul A, Rahman A, Breivik K (2015) High concentrations of organic contaminants in air from ship breaking activities in Chittagong, Bangladesh. Environ Sci Technol 49:11372–11380CrossRefGoogle Scholar
  84. Okay OS, Karacik B, Gungordu A, Ozmen M, Yilmaz A, Koyunbaba NC, Yakan SD, Korkmaz V, Henkelmann B, Schramm KW (2014) Micro-organic pollutants and biological response of mussels in marinas and ship building/breaking yards in Turkey. Sci Total Environ 496:165–178CrossRefGoogle Scholar
  85. OSHA (2001) Shipbreaking fact sheet. U.S. Department of Labor, Occupational Safety and Health Administration, Washington, DCGoogle Scholar
  86. OSHA (2010) Safe work practices for shipbreaking. U.S. Department of Labor, Occupational Safety and Health Administration, Washington, DCGoogle Scholar
  87. Papaioannou D (2003) Environmental implications, related to the shipbuilding and ship repairing activity in Greece. J Marit Transp Sci 41:241–252Google Scholar
  88. Pasha M, Hasan M, Rahman I, Hasnat A (2012) Assessment of ship breaking and recycling industries in Bangladesh—an effective step towards the achievement of environmental sustainability. Paper presented at the International Conference on Agricultural, Environment and Biological Sciences, Phuket, May 26–27Google Scholar
  89. Patel V, Munot H, Shouche YS, Madamwar D (2014) Response of bacterial community structure to seasonal fluctuation and anthropogenic pollution on coastal water of Alang-Sosiya ship breaking yard, Bhavnagar, India. Bioresour Technol 161:362–370CrossRefGoogle Scholar
  90. Qari R, Siddiqui SA, Qureshi NA (2005) A comparative study of heavy metal concentrations in surficial sediments from coastal areas of Karachi, Pakistan. Mar Pollut Bull 50:595–599CrossRefGoogle Scholar
  91. Rahman SMM, Mayer AL (2016) Policy compliance recommendations for international shipbreaking treaties for Bangladesh. Mar Policy 73:122–129CrossRefGoogle Scholar
  92. Rane PV (2014) Echoes of ship breaking (a film of 36:57 min duration). Vega Productions, OwatonnaGoogle Scholar
  93. Reddy MS, Basha S, Kumar VGS, Joshi HV, Ghosh PK (2003) Quantification and classification of ship scraping waste at Alang–Sosiya, India. Mar Pollut Bull 46:1609–1614CrossRefGoogle Scholar
  94. Reddy MS, Basha S, Sravan Kumar VG, Joshi HV, Ramachandraiah G (2004) Distribution, enrichment and accumulation of heavy metals in coastal sediments of Alang–Sosiya ship scrapping yard, India. Mar Pollut Bull 48:1055–1059CrossRefGoogle Scholar
  95. Reddy MS, Basha S, Adimurthy S, Ramachandraiah G (2006) Description of the small plastics fragments in marine sediments along the Alang-Sosiya ship-breaking yard, India. Estuar Coast Shelf Sci 68:656–660CrossRefGoogle Scholar
  96. Rios LM, Moore C, Jones PR (2007) Persistent organic pollutants carried by synthetic polymers in the ocean environment. Mar Pollut Bull 54:1230–1237CrossRefGoogle Scholar
  97. Roberts DA (2012) Causes and ecological effects of resuspended contaminated sediments (RCS) in marine environments. Environ Int 40:230–243CrossRefGoogle Scholar
  98. Rousmaniere P, Raj N (2007) Shipbreaking in the developing world: problems and prospects. Int J Occup Environ Health 13:359–368CrossRefGoogle Scholar
  99. SAJ (2016) Shipbuilding statistics. Shipbuilders’ Association of Japan, TokyoGoogle Scholar
  100. Sarraf M, Stuer-Lauridsen F, Dyoulgerov M, Bloch R, Wingfield S, Watkinson R (2010) Ship breaking and recycling industry in Bangladesh and Pakistan. World Bank, CanadaGoogle Scholar
  101. Sawyer JF (2002) Shipbreaking and the north-south debate: economic development or environmental and labor catastrophe? Penn St Int'l L Rev 20:535–562Google Scholar
  102. Schuler M (2017) 2010-Built Panamax Containership ‘Hammonia Grenada’ Sold for Scrap. gCaptain: Maritime and Offshore Energy Industry News. http://gcaptain.com/2010-built-panamax-containership-hammonia-grenada-sold-for-scrap/. Accessed 6 Feb 2017
  103. Shahzad SM, Javaid U (2016) Development of shipping sector in Pakistan: options and proposed strategy. J Polit Stud 23:537–559Google Scholar
  104. Siddiquee NA, Parween S, Quddus MMA, Barua P (2012) Heavy metal pollution in sediments at ship breaking area of Bangladesh. In: Subramanian V (ed) Coastal Environments: Focus on Asian Regions. Springer Netherlands, pp 78–87Google Scholar
  105. Smith G (2011) Ship breaking industry. Naval-history.Net. http://www.naval-history.net/WW1NavyBritish-Shipbreak.htm. Accessed 7 Feb 2017
  106. Reddy MS, Basha S, Joshi HV, Ramachandraiah G (2005) Seasonal distribution and contamination levels of total PHCs, PAHs and heavy metals in coastal waters of the Alang–Sosiya ship scrapping yard, Gulf of Cambay, India. Chemosphere 61:1587–1593CrossRefGoogle Scholar
  107. Sujauddin M, Koide R, Mohammed Mosharraf H, Murakami S (2012) Material flow analysis on ship breaking and recycling industry in Bangladesh. Paper presented at the EcoBalance 2012 (the 10th international conference on EcoBalance), Yokohama, Japan, November 20–23Google Scholar
  108. Sujauddin M, Koide R, Komatsu T, Hossain MM, Tokoro C, Murakami S (2015) Characterization of ship breaking industry in Bangladesh. J Mater Cycles Waste 17:72–83CrossRefGoogle Scholar
  109. Sujauddin M, Koide R, Komatsu T, Hossain MM, Tokoro C, Murakami S (2017) Ship breaking and the steel industry in Bangladesh: a material flow perspective. J Ind Ecol 21:191–203CrossRefGoogle Scholar
  110. Teuten EL, Rowland SJ, Galloway TS, Thompson RC (2007) Potential for plastics to transport hydrophobic contaminants. Environ Sci Technol 41:7759–7764CrossRefGoogle Scholar
  111. Thompson RC, Olsen Y, Mitchell RP, Davis A, Rowland SJ, John AW, McGonigle D, Russell AE (2004) Lost at sea: where is all the plastic? Science 304:838–838CrossRefGoogle Scholar
  112. UNCTAD (2015) Review of maritime transport. The United Nations Conference on Trade and Development, GenevaGoogle Scholar
  113. UNEP (2003) Technical guidelines for the environmentally sound management of the full and partial dismantling of ships. Secretariat of the Basel Convention, Châtelaine, SwitzerlandGoogle Scholar
  114. UNEP (2013) Feasibility study for ship dismantling. United Nations Environment Programme, NairobiGoogle Scholar
  115. Wang L-F, Yang L-Y, Kong L-H, Li S, Zhu J-R, Wang Y-Q (2014) Spatial distribution, source identification and pollution assessment of metal content in the surface sediments of Nansi Lake, China. J Geochem Explor 140:87–95CrossRefGoogle Scholar
  116. Whitall D, Mason A, Pait A, Brune L, Fulton M, Wirth E, Vandiver L (2014) Organic and metal contamination in marine surface sediments of Guánica Bay, Puerto Rico. Mar Pollut Bull 80:293–301CrossRefGoogle Scholar
  117. Willis S (2010) The Fighting Temeraire. Quercus, LondonGoogle Scholar
  118. Winchester C, Hardy AC, Bowen FC (1936) Shipping wonders of the world. Amalgamated Press, LondonGoogle Scholar
  119. Wu W-T, Lu Y-H, Lin Y-J, Yang Y-H, Shiue H-S, Hsu J-H, Li C-Y, Yang C-Y, Liou S-H, Wu T-N (2013) Mortality among shipbreaking workers in Taiwan—a retrospective cohort study from 1985 to 2008. Am J Ind Med 56:701–708CrossRefGoogle Scholar
  120. Wu W-T, Lin Y-J, Shiue H-S, Li C-Y, Tsai P-J, Yang C-Y, Liou S-H, Wu T-N (2014) Cancer incidence of Taiwanese shipbreaking workers who have been potentially exposed to asbestos. Environ Res 132:370–378CrossRefGoogle Scholar
  121. Yılmaz A, Karacık B, Yakan SD, Henkelmann B, Schramm K-W, Okay OS (2016) Organic and heavy metal pollution in shipbreaking yards. Ocean Eng 123:452–457CrossRefGoogle Scholar
  122. Yujuico E (2014) Demandeur pays: the EU and funding improvements in South Asian ship recycling practices. Transport Res A Policy Pract 67:340–351CrossRefGoogle Scholar
  123. Zarfl C, Matthies M (2010) Are marine plastic particles transport vectors for organic pollutants to the Arctic? Mar Pollut Bull 60:1810–1814CrossRefGoogle Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  1. 1.Graduate School of Natural Science and TechnologyKanazawa UniversityKanazawaJapan
  2. 2.Department of Applied Chemistry and Chemical EngineeringUniversity of ChittagongChittagongBangladesh
  3. 3.Institute of Environmental RadioactivityFukushima University, 1 KanayagawaFukushima CityJapan
  4. 4.Institute of Forestry and Environmental SciencesUniversity of ChittagongChittagongBangladesh
  5. 5.Venture Business Laboratory, Organization of Frontier Science and InnovationKanazawa UniversityKanazawaJapan
  6. 6.Department of Civil EngineeringSouthern UniversityChittagongBangladesh
  7. 7.Department of Industrial EngineeringNational Institute of Technology, Ibaraki CollegeHitachinaka CityJapan
  8. 8.Institute of Science and EngineeringKanazawa UniversityKanazawaJapan

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