Dr. Moinuddin Sarker
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Dr. Moinuddin Sarker

CEO and CTO
Waste Technologies LLC, USA

Highest Degree
PostDoc Fellow in Materials Science from University of Leipzig, Germany

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Biography

Dr. Sarker, the President, CEO and CTO of Waste Technologies, LLC (WTL) since 2013, is the sole owner of the company. He received his Ph.D. in Chemistry from the University of Manchester Institute of Science and Technology (UMIST), Manchester, UK. He also has a Masters and a Bachelors degree, both in Chemistry, from the University of Chittagong, Bangladesh. Dr. Sarker has been the Vice President of Research & Development for NSR since 2005 where he invented the technology which makes up US Patent # 8,927,797 B2 “Method for converting waste plastics to lower – molecular weight hydrocarbons, particularly hydrocarbon fuel materials and the hydrocarbon material produced thereby.” An additional 5 patents are pending. This work has garnered numerous awards both nationally and internationally. In addition to having published more than 110 research articles he acts as Editor-in Chief for 15 renowned international journals, World Research Journal of Physical Chemistry, International Journal of Chemical Research, and the World Research Journal of Environment and Waste Management and Editor of 155 and 175 of peer reviewer of national and international journals. Dr, Sarker wrote 6 books including chapters on Waste Plastic to Fuel. Dr. Sarker is a distinguished member of the following associations, Royal Society of Chemistry (RSC), UK, Member of Institute Physics (MInstP), UK, American Chemical Society (ACS), American Physical Society (APS), American Institute of Chemical Engineering (AIChE), International Union of Pure and Applied Chemistry (IUPAC), Advanced Photon Sources User Group (APS), Chicago, Canadian Society for Chemistry (CSC), Chemical Institute of Canada (CIC), American Council on Renewable Energy (ACORE), CleanTech Forum International, Connecticut Technology Council, Alliance for Clean Energy of New York (ACENY), Society of Automobile Engineering (SAE) International, Society of Plastics Engineers (SPE), Vermont Renewable Energy, Sierra Club, Greenpeace International, Bangladesh Chemical Society (Life Member), Dhaka, Bangladesh, Canadian Institute for Neutron Scattering (CINS) and many more. In addition, Dr. Sarker was elected President of Association of Energy Engineers (AEE)-CT Chapter in August, 2012-14 and advisor board member of CT Green Building Council (CTGBC) since 2013. Dr. Sarker also heads a humanitarian effort in Bangladesh, The Moinuddin and Anjuman Foundation, Inc., (www.moinandanjufoundation.com) which helps provide essentials for the poor and underprivileged in Bangladesh and around the Globe.

Area of Interest:

Physical Science Engineering
100%
Energy
62%
Chemistry
90%
Physics
75%
Material Science
55%

Research Publications in Numbers

Books
0
Chapters
0
Articles
0
Abstracts
0

Selected Publications

  1. Sarker, M. and M.M. Rashid, 2015. Polypropylene Waste Plastic Conversion into Fuel Oil by using Thermal Degradation with Fractional Process. Am.J. Environ., Energy Power Res., 2: 1-10.
  2. Halder, P.K., N. Paul, M.U.H. Joardder and M. Sarker, 2015. Energy scarcity and potential of renewable energy in Bangladesh. Renewable Sustainable Energy Rev., 51: 1636-1649.
    CrossRef  |  Direct Link  |  
  3. Sarker, M., M.M. Rashid and M.S. Rahman, 2014. Randomly mixture of waste plastics conversion into fuel by using leftover residue. J. Ecol. Environ. Sci., 5: 124-132.
  4. Sarker, M. and M.M. Rashid, 2014. Motor vehicle tire and high density polyethylene (HDPE-2) mixture convert into fuel energy using thermal process. Int. J. Waste Manage. Technol., 2: 1-10.
    Direct Link  |  
  5. Rashid, M.M. and M. Sarker, 2014. Dirty waste plastics to crude oil production for refinery. World J. Sci. Technol. Res., 2: 1-13.
    Direct Link  |  
  6. Sarker, M., and M.M. Rashid, 2013. Petroleum Production from Polystyrene Waste Plastic and Standard Polystyrene. Science and Technology Publishing Inc., USA..
  7. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2013. Halogenated hydrocarbon compound fuel produced from PVC and PP waste plastic. Int. J. Energy Eng., 3: 20-27.
  8. Sarker, M. and M.M. Sarker, 2013. Cover of cylinder lattice plastic convert into fuel. Int. Lett. Chem. Phys. Astron., 11: 17-30.
    CrossRef  |  Direct Link  |  
  9. Sarker, M. and M.M. Rashid, 2013. Waste tyre and polypropylene mixture into petroleum fuel using ZnO. Int. J. Innovative Sci. Modern Eng., 1: 1-8.
  10. Sarker, M. and M.M. Rashid, 2013. Waste plastics mixture of polystyrene and polypropylene into light grade fuel using Fe2O3 catalyst. Int. J. Renewable Energy Technol. Res., 2: 17-28.
  11. Sarker, M. and M.M. Rashid, 2013. Thermal degradation of poly (ethylene terephthalate) waste soft drinks bottles and low density polyethylene grocery bags. Int. J. Sustainable Energy Environ., 1: 78-86.
  12. Sarker, M. and M.M. Rashid, 2013. Thermal and catalytic treatment of PVC and HDPE mixture to fuel using NaHCO3. Int. J. Environ. Eng. Sci. Technol. Res., 1: 20-27.
    Direct Link  |  
  13. Sarker, M. and M.M. Rashid, 2013. Study of Environmentally Hazardous HDPE Waste Plastic and Standard HDPE Plastic to Fuel Production Process. ISBN: 978-0-9886890-5-3, Academic and Scientific Publishing.
  14. Sarker, M. and M.M. Rashid, 2013. Production of valuable hydrocarbons by catalytic degradation of a mixture of polyvinyl chloride and polystyrene waste. Int. J. Eng. Technol. Res., 1: 17-26.
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  15. Sarker, M. and M.M. Rashid, 2013. Production of aromatic hydrocarbons related kerosene fuel from polystyrene and polypropylene waste plastics mixture by fractional distillation process. Int. J. Applied Chem. Sci. Res., 1: 10-23.
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  16. Sarker, M. and M.M. Rashid, 2013. Polyethylene terephthalate (Pete) and high density polyethylene (Hdpe) mixture to fuel production. Am. J. Eng. Res., 2: 1-10.
  17. Sarker, M. and M.M. Rashid, 2013. Petroleum refinery feed produce from electronic-waste plastic (E-Waste) using zinc oxide (ZnO) catalyst with activated carbon. Res. J. Pharm. Biol. Chem. Sci., 4: 203-214.
  18. Sarker, M. and M.M. Rashid, 2013. PP, PETE and PS waste plastics mixture into fuel. Mater. Sci. Res. India, 10: 7-16.
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  19. Sarker, M. and M.M. Rashid, 2013. Mixture of waste plastics to fuel production process using catalyst percentage ratio effect study. Int. J. Environ. Eng. Sci. Technol. Res., 1: 1-19.
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  20. Sarker, M. and M.M. Rashid, 2013. Mixture of LDPE, PP and PS waste plastics into fuel by thermolysis process. Int. J. Eng., 1: 1-16.
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  21. Sarker, M. and M.M. Rashid, 2013. Hydrocarbon fuel analysis by gas chromatography and mass spectrometer with hexane solvent. Int. J. Eng. Technol., 13: 23-32.
  22. Sarker, M. and M.M. Rashid, 2013. Hydrocarbon compounds fuel recover from LDPE/HDPE/PP/PS waste plastics mixture using zinc oxide catalyst. Int. J. Sustainable Energy Environ., 1: 14-24.
    Direct Link  |  
  23. Sarker, M. and M.M. Rashid, 2013. High energy content liquid hydrocarbon fuel from mixture of polypropylene and polystyrene waste plastics using thermal cracking and activated carbon. Int. J. Bioassays, 2: 341-348.
    Direct Link  |  
  24. Sarker, M. and M.M. Rashid, 2013. Food container waste plastic conversion into fuel. Int. J. Eng. Applied Sci., 3: 1-16.
    Direct Link  |  
  25. Sarker, M. and M.M. Rashid, 2013. Catalytic conversion of low density polyethylene and polyvinyl chloride mixture into fuel using Al2O3. Int. J. Mater. Methods Technol., 1: 8-16.
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  26. Sarker, M. and M.M. Rashid, 2013. Waste polymer resin conversion into petroleum oil for refinery industry. Int. J. Applied Chem. Sci. Res., 1: 1-9.
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  27. Rashid, M.M. and M. Sarker, 2013. Waste polyethylene terephthalate (PETE) and polystyrene (PS) into fuel. Int. J. Sci. Technol. Res., 2: 176-189.
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  28. Rashid, M.M. and M. Sarker, 2013. Polypropylene and polystyrene waste plastics mixture to diesel fuel for truck/bus engines. Int. J. Eng. Sci. Inv., 2: 62-68.
  29. Rashid, M.M. and M. Sarker, 2013. Liquid fuels and chemicals from several plastic wastes and motor vehicle tire mixture by catalytic cracking. Am. J. Environ. Energy and Power Res., 1: 108-116.
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  30. Rashid, M.M. and M. Sarker, 2013. Fuel oil and home heating oil produce from polystyrene and polypropylene waste plastics mixture. Int. J. Waste Manage. Technol., 1: 77-86.
  31. Rashid, M.M. and M. Sarker, 2013. Construction waste plastic and household mixed plastics mixture to crude fuel. Int. J. Waste Manage. Technol., 1: 103-116.
  32. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Thermal degradation of PVC and mixed waste plastics to produce mixture of hydrocarbon fuel. J. Applied Chem. Sci., 1: 9-17.
  33. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Thermal conversion of waste polyolefin of PS to low sulfur diesel grade fuel with activated carbon by fractional process. Int. J. Chem. Anal. Sci., 3: 1425-1429.
  34. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Production of valuable heavy hydrocarbon fuel oil by thermal degradation process of post-consumer municipal polystyrene (PS) waste plastic in steel reactor. Energy Power, 2: 89-95.
    CrossRef  |  Direct Link  |  
  35. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Polystyrene (PS) waste plastic conversion into aviation/kerosene category of fuel by using fractional column distillation process. Int. J. Energy Environ., 3: 871-880.
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  36. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Polypropylene (PP) waste plastic into light fractional gasoline grade fuel for vehicle by using two step thermal processes. Int. J. For. Soil Erosion, 2: 186-191.
  37. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Liquid fuel obtain from polypropylene (PP-5) and high density polyethylene (HDPE-2) waste plastics mixture. J. Int. Sci., 5: 368-378.
  38. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Fractional distillation process utilized to produce light fractional fuel from low density polyethylene (LDPE) waste plastic. Open Fuels Energy Sci. J., 5: 39-46.
    Direct Link  |  
  39. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Environmentally harmful low density waste plastic conversion into kerosene grade fuel. J. Environ. Prot., 3: 700-708.
    CrossRef  |  Direct Link  |  
  40. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Conversion of low density polyethylene (LDPE) and polypropylene (PP) waste plastics into liquid fuel using thermal cracking process. Br. J. Environ. Climate Change, 2: 1-11.
  41. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. Aromatic light hydrocarbon fuel generation from municipal polystyrene (PS) waste plastic by using low temperature fractional distillation process. Int. J. Environ. Prot., 2: 1-10.
  42. Sarker, M., M.M. Rashid, M.S. Rahman and M. Molla, 2012. A new kind of renewable energy: Production of aromatic hydrocarbons naphtha chemical by thermal degradation of polystyrene (PS) waste plastic. Am. J. Climate Change, 1: 145-153.
    CrossRef  |  Direct Link  |  
  43. Sarker, M., M.M. Rashid, M.S. Rahman and M. Moll, 2012. Alternative diesel grade fuel transformed from polypropylene (PP) municipal waste plastic using thermal cracking with fractional column distillation. J. Energy Power Eng., 4: 165-172.
    CrossRef  |  Direct Link  |  
  44. Sarker, M., M.M. Rashid, M.S Rahman and M. Molla, 2012. Low and high density polyethylene waste plastics conversion into liquid hydrocarbon fuel. Sustainability Green Chem., 30: 42-43.
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  45. Sarker, M., M.M. Rashid, M.S Rahman and M. Molla, 2012. Chemical products produced from high density polyethylene (HDPE) waste plastic. Int. J. Mater. Sci., 2: 56-62.
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  46. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2012. Un-proportional municipal waste plastic conversion into fuel using activated carbon and HZSM-5 catalyst. J. Applied Chem. Sci., 4: 1-8.
  47. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2012. Thermal conversion of waste plastics (HDPE, PP and PS) to produce mixture of hydrocarbons. Am. J. Environ. Eng., 2: 128-136.
    CrossRef  |  Direct Link  |  
  48. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2012. Method of converting municipal proportional waste plastics into liquid hydrocarbon fuel by using activated carbon. Int. J. Mater. Chem., 2: 208-217.
    CrossRef  |  Direct Link  |  
  49. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2012. Light hydrocarbons produced from high density polyethylene (HDPE) waste using fractional column distillation. Int. J. Sci. Eng. Res., 3: 1-10.
  50. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2012. High density polyethylene (HDPE-2) and polystyrene (PS-6) waste plastic mixture turns into valuable fuel energy. J. Int. Sci., 5: 379-386.
  51. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2012. Heavy oil produced from municipal mixed waste plastics by fractional distillation process. BIOINFO Renewable Sustainable, 2: 5-11.
  52. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2012. A new technology proposed to recycle waste plastics into hydrocarbon fuel in USA. Int. J. Energy Environ., 3: 749-760.
    Direct Link  |  
  53. Sarker, M., M.M. Rashid, M. Molla and A. Zaman, 2012. Conversion of municipal waste plastic into liquid hydrocarbon fuel using a stainless steel reactor. J. Environ. Sci. Eng., 1: 721-726.
  54. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Unconventional liquid fuel from municipality waste plastics mixture of polystyrene (PS) and Low Density Polyethylene (LDPE). Int. J. Applied Environ. Sci., 7: 415-426.
  55. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Transforming fuel from municipal waste plastic by using of nickel silica {Ni (SiO2)} catalyst. Int. J. Chem. Environ. Pharmaceut. Res., 3: 109-116.
  56. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Thermal conversion of polymer wastes (LDPE) into hydrocarbon diesel fuel without cracking catalysts. Int. J. Pure Applied Sci. Technol., 11: 36-44.
  57. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Short and long chain hydrocarbon transformed from waste plastics. Int. J. Chem. Eng. Res., 4: 79-90.
  58. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Renewable diesel fuel generated from high density polyethylene (HDPE) waste plastic by using fractional distillation process. Int. J. Eng. Res. Technol., 5: 389-398.
  59. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Randomly mixture of waste plastics conversion into fuel by using leftover residue. World Res. J. Environ. Waste Manag., 1: 1-10.
  60. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. None coded waste plastics conversion into fuel. Int. J. Eng. Res. Applic., 2: 444-449.
  61. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Low density polyethylene (LDPE) waste plastic transform into renewable heavy fuel by using thermal cracking. World Environ., 2: 140-147.
    CrossRef  |  Direct Link  |  
  62. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. High Density Polyethylene (HDPE) waste plastic conversion into alternative fuel for heavy vehicle. J. Environ. Res. Dev., 7: 1-9.
  63. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Conventional naphtha chemical produced from municipal solid low density polyethylene (LDPE) waste plastic. Int. J. Applied Chem., 8: 153-163.
  64. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Conventional fuel generated from polypropylene (PP) waste plastic like kerosene/jet/aviation grade with activated carbon. Int. J. Mod. Eng. Res., 2: 2168-2173.
  65. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Composition of hydrocarbon type fuels formed in thermal decomposition of municipal solid waste plastics and calcium carbonate. Mater. Environ. Sci., 1: 114-123.
  66. Sarker, M., M.M. Rashid and M.S. Rahman, 2012. Alternative naphtha grade fuel produced from Polypropylene (PP) waste plastic by using distillation process. J. Thermal Energy Power Eng., 1: 11-15.
  67. Sarker, M., M.M. Rashid and M.R. Rahman, 2012. Randomly mixture waste plastics and sodium carbonate (Na2CO3) mixture into renewable petroleum product. Int. J. Eng. Res. Ind. Appl., 5: 51-70.
  68. Sarker, M., M.M. Rashid and M. Molla, 2012. Waste polypropylene plastic conversion into liquid hydrocarbon fuel for producing electricity and energies. J. Environ. Technol., 33: 2709-2721.
    CrossRef  |  Direct Link  |  
  69. Sarker, M., M.M. Rashid and M. Molla, 2012. First waste plastic conversion into liquid fuel by using muffle furnace through reactor. Int. J. Energy Eng., 2: 293-303.
    CrossRef  |  Direct Link  |  
  70. Sarker, M. and M.M. Rashid, 2012. Polyvinyl chloride (PVC) waste plastic treatment using zinc oxide (ZnO) with activated carbon and produced hydrocarbon fuel for petroleum refinery. Int. J. Eng. Sci., 1: 29-41.
  71. Sarker, M. and M.M. Rashid, 2012. Motor vehicle used tire conversion into fuel using thermal degradation process with ferric carbonate catalyst. Int. J. Eng. Inv., 1: 5-13.
    Direct Link  |  
  72. Sarker, M. and M.M. Rashid, 2012. First simple and easy process of thermal degrading municipal waste plastics into fuel resource. J. Eng., 2: 38-49.
  73. Sarker, M. and M.M. Rashid, 2012. E-Waste cable plastic transforming oil using sodium hydroxide with activated carbon. Int. J. Sci. Res., 1: 168-172.
    Direct Link  |  
  74. Sarker, M. and M.M. Rashid, 2012. Crude oil production for refinery petroleum industry from all kind of polymer waste using ferric oxide (Fe2O3) catalyst. Int. J. Renewable Energy Technol. Res., 1: 30-38.
    Direct Link  |  
  75. Sarker, M. and M.M. Rashid, 2012. Catalytic degradation of PVC and PETE mixture of waste plastic into petrochemicals using Al2O3 and activated carbon. Int. J. Renewable Energy Technol. Res., 1: 39-48.
    Direct Link  |  
  76. Moinuddin, S., M.R. Mohammad, S.R. Muhammad and M. Mohammed, 2012. Jet category fuel produced from high density polyetylene (HDPE) waste plastic by using thermal cracking with fractional distillation column process. Trans. J. Sci. Technol., 2: 1-11.
  77. Sarker, M., M.S. Rahman, M.M. Rashid and M. Molla, 2011. Waste sneaker conversion into liquid hydrocarbon fuel. J. Mater. Sci. Eng., 5: 583-588.
  78. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2011. Waste Plastics influence on environment and its solution to create an alternate energy source. J. Green Chem. Chimica, 29: 50-51.
  79. Sarker, M., M.M. Rashid, M. Molla and M.S. Rahman, 2011. Different types of fuel produce from municipal solid mixed waste plastics by fractional distillation with thermal cracking process. Int. Rev. Chem. Eng., 3: 449-456.
  80. Sarker, M., M.M. Rashid, M. Molla and A. Zaman, 2011. De-polymerization of waste polymers to produce hydrocarbon fuel utilizing thermal degradation. J. Chem. Chem. Eng., 5: 129-134.
  81. Sarker, M., M.M. Rashid, A. Zaman and M. Molla, 2011. Thermal and catalytic conversion of waste plastics into hydrocarbon materials. J. Mater. Sci. Eng., 5: 298-303.
  82. Sarker, M., M.M. Rashid, A. Zaman and M. Molla, 2011. Generation of transportation fuel from solid municipal waste plastics. J. Environ. Sci. Eng., 5: 57-62.
  83. Sarker, M., M.M. Rashid, A. Zaman and M. Molla, 2011. Alternative gasoline produce from abundant solid waste plastics. J. Mater. Sci. Eng., 5: 394-399.
  84. Sarker, M., M.M. Rashid and M.S. Rahman, 2011. Agricultural waste plastics conversion into high energy liquid hydrocarbon fuel by thermal degradation process. J. Petroleum Technol. Altern. Fuels, 2: 141-145.
    Direct Link  |  
  85. Sarker, M., M.M. Rashid and M. Molla, 2011. Waste plastic conversion into hydrocarbon fuel materials. J. Environ. Sci. Eng., 5: 603-609.
  86. Sarker, M., M.M. Rashid and M. Molla, 2011. Waste plastic conversion into hydrocarbon fuel like low sulfur diesel. J. Environ. Sci. Eng., 5: 446-452.
    Direct Link  |  
  87. Sarker, M., M.M. Rashid and M. Molla, 2011. Waste plastic conversion into chemical product like naphtha. J. Fundam. Renew. Energy Applic., Vol. 1. 10.4303/jfrea/R110101.
    CrossRef  |  Direct Link  |  
  88. Sarker, M., M.M. Rashid and M. Molla, 2011. Power generation from municipal solid waste plastics. J. Energy Power Eng., 5: 489-494.
  89. Sarker, M., M.M. Rashid and M. Molla, 2011. New renewable source of energy from municipal solid waste plastics. J. Environ. Sci. Eng., 5: 309-315.
  90. Sarker, M., M.M. Rashid and M. Molla, 2011. New alternative vehicle hydrocarbon liquid fuels from municipal solid waste plastics. J. Fundam. Renew. Energy Applic., Vol. 1. 10.4303/jfrea/R101201.
    CrossRef  |  Direct Link  |  
  91. Sarker, M., M.M. Rashid and M. Molla, 2011. Municipal waste plastics conversion into aviation fuel. J. Energy Power Eng., 5: 620-626.
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  92. Sarker, M., M.M. Rashid and M. Molla, 2011. Liquid hydrocarbon fuel conversion from abundant solid waste low density polyethylene (LDPE-4) plastics. Int. Rev. Chem. Eng., 3: 340-349.
  93. Sarker, M., M.M. Rashid and M. Molla, 2011. Abundant high-density polyethylene (HDPE-2) turns into fuel by using of HZSM-5 catalyst. J. Fundam Renew Energy Applic., Vol. 1. .
    Direct Link  |  
  94. Sarker, M., A. Kabir, M.M. Rashid, M. Molla and A.D. Mohammad, 2011. Waste polyethylene terephthalate (PETE-1) conversion into liquid fuel. J. Fundam. Renew. Energy Applic., Vol. 1. 10.4303/jfrea/R101202.
    CrossRef  |  Direct Link  |  
  95. Sarker, M., 2011. Municipal Waste Plastic Conversion Into Different Category Liquid Hydrocarbon Fuel. INTECH Open, Europe, ISBN: 978-3-659-11347-5.
  96. Sarker, M., 2011. Alternative fuels derived from solid waste plastics. J. Environ. Sci. Eng., 5: 316-322.

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