References
- Abbas, A. S. and D. A. Sawsan. 2008. Shubar. pyrolysis of high-density polyethylene for the production of fuel-like liquid hydrocarbon. Iraqi Journal of Chemical and Petroleum Engineering 9(1):23–29.
- Aguado, J., D. P. Serrano, F. Garagorri, and Fernández, J. A. 2000. Catalytic conversion of polyolefins into fuels over zeolite beta. Polymer Degradation and Stability 69:11–16.
- Ali, S., A. A. Garforth, D. H. Harris, D. J. Rawlence, and Y. Uemichi. 2002. Polymer waste recycling over “used” catalysts. Catalysis Today 75:247–55.
- Ali, M. F., M. Nahid, and S. S. H. H. Redhwi. 2004. Study on the conversion of waste plastics/petroleum resid mixtures to transportation fuels. Journal of Material Cycles and Waste Management 6:27–34.
- Al-Salem, S. M., P. Lettieri, and J. Baeyens. 2009. Recycling and recovery routes of plastic solid waste (PSW): A review. Waste Management, 29(10):2625–43.
- Al-Salem, S. M., P. Lettieri, and J. Baeyens. 2010. The valorization of plastic solid waste (PSW) by primary to quaternary routes: From re-use to energy and chemicals. Progress in Energy and Combustion Science 36(1):103–29.
- Angyal, A., N. Miskolczi, and L. Bartha. 2007. Petrochemical feedstock by thermal cracking of plastic waste. Journal of Analytical and Applied Pyrolysis 79(1):409–14.
- ASTM. 1979. Annual book of ASTM Standard, Part 23 American Society of Testing Materials. Philadephia, PA.
- Barışçı, S. and M. SalimÖncel. 2014. The Disposal of combed cotton wastes by pyrolysis. International Journal of Green Energy 11 (3):255–66.
- Costa, P., F. Pinto, A. M. Ramos, I. Gulyurtlu, I. Cabrita, and M. S. Bernardo. 2010. Study of the pyrolysis kinetics of a mixture of polyethylene, polypropylene, and polystyrene. Energy & Fuels 24(12):6239–47.
- Demirbas, A. 2004. Pyrolysis of municipal plastic wastes for recovery of gasoline-range hydrocarbons. Journal of Analytical and Applied Pyrolysis 72(1):97–102.
- Ding, F., L. Xiong, C. Luo, H. Zhang, and X. Chen. 2012. Kinetic study of low-temperature conversion of plastic mixtures to value added products. Journal of Analytical and Applied Pyrolysis 94:83–90.
- Encinar, J. M. and J. F. González. 2008. Pyrolysis of synthetic polymers and plastic wastes. Kinetic study. Fuel Processing Technology 89(7):678–86.
- Hakki Metecan, I., A. R. Ozkan, R. Isler, J. Yanik, M. Saglam, and M. Yuksel. 2005. Naphtha derived from polyolefins. Fuel 84(5):619–28.
- Jan, M. R; J. Shah, and H. Gulab. 2010. Catalytic degradation of waste high-density polyethylene into fuel products using BaCO3 as a catalyst. Fuel Processing Technology 91:1428–37.
- Jin, L. E., L. Wang, L. Su, and Q. Cao. 2012. Characteristics of gases from co-pyrolysis of sawdust and tires. International Journal of Green Energy 9(8):719–30.
- Kiran, Ciliz, N., E. Ekinci, and C. E. Snape. 2004. Pyrolysis of virgin and waste polypropylene and its mixtures with waste polyethylene and polystyrene. Waste Management 24(2):173–81.
- Kodera, Y., Y. Ishihara, and T. Kuroki. 2006. Novel process for recycling waste plastics to fuel gas using a moving-bed reactor. Energy & Fuels 20(1):155–58.
- Lee, J. Y., S. M. Park, S. K. Saha, S. J. Cho, and G. Seo. 2011. Liquid-phase degradation of polyethylene (PE) over MFI zeolites with mesopores: Effects of the structure of PE and the characteristics of mesopores. Applied Catalysis B: Environmental 108:61–71.
- Lin, Y. H. 2009. Production of valuable hydrocarbons by catalytic degradation of a mixture of post-consumer plastic waste in a fluidized-bed reactor. Polymer Degradation and Stability 94(11):1924–31.
- Lin, H. T., M. S. Huang, J. W. Luo, L. H. Lin, C. M. Lee, and K. L. Ou. 2010a. Hydrocarbon fuels produced by catalytic pyrolysis of hospital plastic wastes in a fluidizing cracking process. Fuel Processing Technology 91(11):1355–63.
- Lin, Y. H., M. H. Yang, T. T. Wei, C. T. Hsu, K. J. Wu, and S. L. Lee. 2010b. Acid-catalyzed conversion of chlorinated plastic waste into valuable hydrocarbons over post-use commercial FCC catalysts. Journal of Analytical and Applied Pyrolysis 87(1):154–62.
- Mendes, M. R., T. Aramaki, and K. Hanaki. 2004. Comparison of the environmental impact of incineration and landfilling in São Paulo City as determined by LCA. Resources, Conservation and Recycling 41(1):47–63.
- Mills, N. 2005. Plastics: Microstructure and Engineering Applications. Butterworth-Heinemann.
- Miskolczi, N., L. Bartha, and G. Deák. 2006. Thermal degradation of polyethylene and polystyrene from the packaging industry over different catalysts into fuel-like feed stocks. Polymer Degradation and Stability 91(3):517–26.
- Miskolczi, N., L. Bartha, G. Deak, and B. Jover. 2004a. Thermal degradation of municipal plastic waste for production of fuel-like hydrocarbons. Polymer Degradation and Stability 86(2):357–66.
- Miskolczi, N., L. Bartha,G. Deak, B. Jover, and D. Kallo. 2004b. Thermal and thermo-catalytic degradation of high-density polyethylene waste. Journal of Analytical and Applied Pyrolysis 72(2):235–42.
- Naima, K. and A. Liazid. 2013. Waste oils as alternative fuel for diesel engine: A review. Journal of Petroleum Technology and Alternative Fuels 4(3):30–43.
- Ng, S. H., H. Seoud, M. Stanciulescu, and Y. Sugimoto. 1995. Conversion of polyethylene to transportation fuels through pyrolysis and catalytic cracking. Energy & Fuels 9(5),735–42.
- Panda, A. K., R. K. Singh, and D. K. Mishra. 2010. Thermolysis of waste plastics to liquid fuel: A suitable method for plastic waste management and manufacture of value added products—A world prospective. Renewable and Sustainable Energy Reviews 14(1):233–48.
- Pinto, F., P. Costa, I. Gulyurtto, and I. Cabirta. 1999. Effect of Experimental Parameters on Plastics Pyrolysis Reactions, Paper Presented at the R99 Congress, Feb.1.
- Rodriguez, F. 1989. Principles of Polymer Systems. 3rd ed. Washington, DC: Hemisphere, 241.
- Rowe, R. K. and H. P. Sangam. 2002. Durability of HDPE geomembranes. Geotextiles and Geomembranes 20(2):77–95.
- Salmiaton, A. and A. Garforth. 2007. Waste catalysts for waste polymer. Waste Management 27(12):1891–96.
- Shah, J., M. R. Jan, and F. Mabood. 2007. Catalytic conversion of waste tyres into valuable hydrocarbons. Journal of Polymers and the Environment 15:207–11.
- Shah, J., M. R. Jan, and F. Mabood. 2009. Recovery of value-added products from the catalytic pyrolysis of waste tyre. Energy Conversion and Management 50:991–94.
- Shakirullah, M., I. Ahmad, W. Ahmad, and M. Ishaq. 2010. Oxidative desulphurization study of gasoline and kerosene: Role of some organic and inorganic oxidants. Fuel Processing Technology 91(11):1736–41.
- Sharratt, P. N., Y. H. Lin, A. A. Garforth, and J. Dwyer. 1997. Investigation of the catalytic pyrolysis of high-density polyethylene over a HZSM-5 catalyst in a laboratory fluidized-bed reactor. Industrial & Engineering Chemistry Research 36(12):5118–24.
- Speight, J. G. and J. G. Speight. 2002. Handbook of petroleum product analysis. New Jersey: Wiley-Inter Science.
- Subramanian, P. M. 2000. Plastics recycling and waste management in the US. Resources, Conservation and Recycling 28(3):253–63.
- Valerio, F. 2010. Environmental impacts of post-consumer material managements: Recycling, biological treatments, incineration. Waste Management 30(11):2354–61.
- Vasudevan, R., A. Ramalinga Chandra Sekar, B. Sundarakannan, and R. Velkennedy. 2012. A technique to dispose waste plastics in an ecofriendly way–Application in construction of flexible pavements. Construction and Building Materials 28(1):311–20.
- Yasin, G., M. I. Bhanger, T. M. Ansari, S. M. S. R. Naqvi, and F. N. Talpur. 2012. Quality of commercial high speed diesel and its environmental impact. Journal of Petroleum Technology and Alternative Fuels 3(3):29–35.
- Zhang, G. H., J. F. Zhu, and A. Okuwaki. 2007. Prospect and current status of recycling waste plastics and technology for converting them into oil in China. Resources, Conservation and Recycling 50(3):231–39.