Sifat limbah plastik yang sulit diurai oleh alam manjadi latar belakang penelitian mengenai pengolahan plastik yang ramah lingkungan. Pirolisis selain mampu mengolah plastik dengan aman, juga menghasilkan produk cair yang bisa menjadi alternatif sumber bahan bakar. Penelitian yang  dilakukan sebelumnya menunjukkan hasil pirolisis dengan karakteristik yang berbeda-beda tergantung pada jenis plastik yang diolah. Suhu tinggi dan rendemen hasil menjadi kendala yang perlu dipecahkan dalam proses pirolisis limbah plastik. Penggunaan katalis zeolit alam diharapkan dapat meningkatkan rendemen hasil dan menurunkan suhu proses  pirolisis plastik HDPE, sehingga didapat produk cair yang mendekati karakteristik bahan bakar cair bensin. Rasio penggunaan katalis, suhu proses dan karakteristik produk cair yang didapat merupakan variabel yang akan diamati dalam penelitian ini. Nilai specific gravity, pour point dan flash point yang mendekati karakteristik bensin, serta hasil pembacaan GC-MS produk dijadikan parameter yang menentukan keberhasilan penelitian ini.

Achyut Kumar Panda, 2011, Studies on process optimization for production of liquid fuels from waste plastics, Chemical Engineering Department, National Institute of Technology, Rourkela 769008

A.U. Zadgaonkar, 2004, Environmental Protection from Plastic Waste Menace. GPEC

C. Vasile, H. Pakdel, B. Mihai, P. Onu, H. Darie, S. Ciocalteu, 2001, Thermal and catalyticdecomposition of mixed plastics, Journal of Analytical and Applied Pyrolysis 57, pp: 287–303.

Demirbas A. , 2004, Pyrolysis of municipal plastic waste for recovery of gasoline range hydrocarbons. J. Anal. Appl. Pyrolysis, 72: 97-102.

D.P. Serrano, J. Aguado, J.M. Escola, E. Garagorri, J.M. Rodríguez, L.Morselli, G. Palazzi, R. Orsi, 2004, Feedstock recycling of agriculture plastic filmwastes by catalytic cracking, Applied Catalysis B: Environmental 49 : 257–265.

Faravelli T, Pinciroli M, Pisano F, Bozzano G, Dente M, Ranzi E., 2001, Thermal Degradation of polystyrene. J. Anal. Appl. Pyrolysis, 60: 103-121.

Gao.I.F., 2006, Optimation of Plastic Pyrolysis for Liquid Fuel, Conference Proceeding of Chemeca, Knowledge and Innovation

Garforth A, Lin YH, Sharratt PN, Dwyer J., 1998, Production of hydrocarbons by catalytic degradation of high density polyethylene in a laboratory fluidized-bed reactor. Appl Catal, A-Gen, 169(2):331-342.

G.G. Luo, T.T. Suto, S.S. Yasu, K.K. Kato, 2000, Catalytic degradation of high densitypolyethylene and polypropylene into liquid fuel in a powder-particle fluidizedbed, Polymer Degradation and Stability, 70, 97–102.

G. Manos, A. Garforth, J. Dwyer, 2000, Catalytic degradation of high-density poly-ethylene over different zeolitic structures, Industrial & Engineering Chemistry Research 39 , 1198–1202.

G. San Miguel, D.P. Serrano, J. Aguado, 2009, Valorization of waste agricultural poly-ethylene film by sequential pyrolysis and catalytic reforming, Industrial &Engineering Chemistry Research 48, 8697–8703

Lopez, A., 2011, Influence of Time and Temperature on Pyrolysis of Plastic Waste in a Semibatch Reactor. Elsevier, vol. 173.

Mastral FJ, Esperanza E, Garcia P, Juste M., 2002, Pyrolysis of high-denstity polyethylene in a fluidized bed reactor. Influence of the temperature and residence time. J. Anal Appl. Pyrolysis, 63(1): 1-15

Mc Murry, . 2000, J. Organic chemistry. Fifth edition ed . Vol. 5, Pacific Grove : Brooks/Cole. 172.

Murata K, Sato K, Sakata Y, 2004, Effect of pressure on thermal degradation of polyethylene. J. Anal. Appl. Pyrolysis, 71: 569-589.

Nurhadi, M., Characterization and modification of natural zeolite and its cracking properties on petroleum fraction, Indonesian Journal of Chemistry,

Ohkita H, Nishiyama R, Tochihara Y, Mizushima T, Kakuta N, Morioka Y., 1993, Acid properties of silica-alumina catalyst and catalytic degradation of polyethylene. Ind Eng Chem Res, 32(12): 3112-3116.

Park DW, Hwang EY, Kim JR, Choi JK, Kim YA, Woo HC., 1999, Catalytic degradation of polyethylene over solid acid catalysts. Polym Degrad Stabil, 65(2): 193-198.

Pinto, F., 1999, Pyrolysis of Plastic Waste, Effect of Plastic Waste Composition on Product Yield. Elsevier, vol. 51.

Sarker, M., 2012, Thermal Conversion of Waste Plastic (HDPE, PP, PS) to produce Mixture of Hydrocarbons. American Hournal of Environmental Engineering, 2(5):128-136.

Sarker, M., 2012, First Simple and Easy Process of Thermal Degrading Municipal Waste Plastic into Fuel Resource. IOSR Journal of Engineering, vol. 2, Issue 9, pp 38-49.

S. Chaianansutcharit, R. Katsutath, A. Chaisuwan, T. Bhaskar, A. Nigo, A. Muto, Y.Sakata, 2007, Catalytic degradation of polyolefins over hexagonal mesoporous silica:effect of aluminum addition, Journal of Analytical and Applied Pyrolysis 80, 360–368.

Simon, C.M., W. Kaminsky, and B. Schlesselmann, 1996, Pyrolysis of polyolefins with steam to yield olefins. Journal of Analytical and Applied Pyrolysis, 38: p. 75-87.

Sorum L, Gronli MG, Hustad JE., 2001, Pyrolysis characteristic and kinetics of municipal solid wastes. Fuel, 80: 1217-1227.

Sumarni, 2008, Kinetika Reaksi Pirolisis Plastik Low Density Poliethylene (LDPE). Jurusan Teknik Kimia, Institut Sains & Teknologi AKPRIND Yogyakarta

Vasile, C., 2001, Thermal and catalytic decomposition of mixed plastics, Journal of analytical and Applied Pyrolysis, 57, 287-303

Y.-H. Lin, M.-H. Yang, T.-F. Yeh, M.-D. Ger, 2004, Catalytic degradation of high densitypolyethylene over mesoporous and microporous catalysts in a fluidised-bedreactor, Polymer Degradation and Stability 86, 121–128.

Yuanita, D., 2010, Kajian modifikasi dan karakterisasi zeolit alam dari berbagai negara, prosiding seminar nasional kimia dan pendidikan kimia 2010.

Z.S. Seddegi, U. Budrthumal, A.A. Al-Arfaj, A.M. Al-Amer, S.A.I. Barri, 2002, Catalyticcracking of polyethylene over all-silica MCM-41 molecular sieve, Applied Catal-ysis A: General 225 , 167–176.