-مراجع
[1] Kumar, A. and A. Agrawal, Recent trends in solid waste management status, challenges, and potential for the future Indian cities–A review. Current Research in Environmental Sustainability. 2: p. 100011(2020).
[3] Samadder SR, Prabhakar R, Khan D, Kishan D, Chauha MS.
Analysis of the contaminants released from municipal solid waste landfill site: A case study. Science of The Total Environment 580:593-601(2017).
[4] Horak J, Kubonova L, Bajer S, Dej M, Hopan F, Krpec K, Ochodek T.
Composition of ashes from the combustion of solid fuels and municipal waste in households. Journal of Environmental Management 248:1-6(2019).
[5] Hoareau CE, Ahmad N, Nuid M, Rubiyatno, Khoi DN, Kristanti RA.
Sustainable technology in developed countries: Waste municipal management.
Industrial and Domestic Waste Management 1:48-55(2021).
[7] Rehan M, Nizami AS, Shahzad K, Ouda OK, Ismail IM, Almeelbi T, Iqbal T, Demirbas A.
Pyrolytic Liquid Fuel: a Source of Renewable Electricity Generation in Makkah. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects. 1;38(17):2598-603(2016).
[8] Howell SG.
A ten Year Review of Plastics Recycling. Journal of hazardous materials. 1;29(2):143-64(1992)
[9] Li Q, Faramarzi A, Zhang S, Wang Y, Hu X, Gholizadeh M. Progress in catalytic pyrolysis of municipal solid waste. Energy Conversion and Management 226:1-30(2020).
[10] Labaki M, Jeguirim M.
Thermochemical conversion of waste tyres-a review. Environmental Science and Pollution Research 24:9962-9992(2017).
[11] Hasan MM, Rasul MG, Jahirul MI, Mofijur M. Fuelling the future: Unleashing energy and exergy efficiency from municipal green waste pyrolysis. Fuel 357:1-15(2024).
[12] Tiwari M, Dirbeba MJ, Lehmusto J, Yrjas P, Vinu R. Analytical and applied pyrolysis of challenging biomass feedstocks: Effect of pyrolysis conditions on product yield and composition. Journal of Analytical and Applied Pyrolysis 177:1-24(2024).
[13] Wang J, Ma Y, Li S, Yue C. Catalytic pyrolysis of polystyrene in different reactors: Effects of operating conditions on distribution and composition of products. Journal of Analytical and Applied Pyrolysis 177:1-10(2024).
[14] Williams PT.
Yield and Composition of Gases and Oils/Waxes from the Feedstock Recycling of Waste Plastic. Feedstock Recycling and Pyrolysis of Waste Plastics:
Converting Waste Plastics into Diesel and Other Fuels. 24:285-313(2006).
[17] Ke L, Wu Q, Zhou N, Li H, Zhang Q, Cui X, Fan L, Liu Y, Cobb K, Ruan R, Wang Y. Polyethylene upcycling to aromatics by pulse pressurized catalytic pyrolysis. Journal of Hazardous Materials. 461:1-17(2024).
[18] Valizadeh S, Valizadeh B, Seo MW, Choi YJ, Lee J, Chen WH, Lin KYA, Park YK. Recent advances in liquid fuel production from plastic waste via pyrolysis: Emphasis on polyolefins and polystyrene. Environmental Research 246:1-9(2024).
[19] Karak, T., R. Bhagat, and P. Bhattacharyya, Municipal solid waste generation, composition, and management: The world scenario. Critical Reviews in Environmental Science and Technology, 43(2): p. 215-215 (2013).
[20] D.K. Ojha, R. Vinu. Fast co-pyrolysis of cellulose and polypropylene using Py-GC/MS and Py-FT-IR. RSC Adv. 5, 66861-70 (2015).
[21] Y. Xue. Thermochemical conversion of organic and plastic waste materials through pyrolysis, Iowa State University (2017).
[22] J. Wang, Q. Liu, J. Zhou, Z. Yu. Production of High-Value Chemicals by Biomass Pyrolysis with Metal Oxides and Zeolites. Waste Biomass Valori. (2020) 1-9.45:1509-1630(2011).
[23] Nawaz A, Razzak SA. Co-pyrolysis of biomass and different plastic waste to reduce hazardous waste and subsequent production of energy products: A review on advancement, synergies, and future prospects. Renewable Energy 224:1-18(2024).
[25] Salavati S, Zhang C, Zhang S, Liu Q, Gholizadeh M, Hu X.
Cross-interaction during co-gasification of wood, weed, plastic, tire and carton. Journal of Environmental Management 250:1-15(2019).
[26] Xu S, Lai D, Zeng X, Zhang L, Han Z, Cheng J, Wu R, Masek O, Xu G.
Pyrolysis characteristics of waste tire particles in fixed-bed reactor with internals. Carbon Resources Conversion 1:228-237(2018).
[27] Ahmadi A, Gholizadeh M, Fallahi-Samberan M, Amirkhani L. Pyrolysis of municipal waste: Effect of waste type and co-pyrolysis on the formation of products and coke over zeolite catalyst. Chemical Engineering Research and Design 1:1-33(2022).
[28] Han H, Wang R, Bao Z. Effect of secondary flow and secondary reactions on pyrolysis and heat transfer of supercritical hydrocarbon aviation fuel in a U-bend tube. Energy 292:1-8(2024).
[29] Zheng K, Hu S, Li A, Ren Q, Xu K, Xu J, Jiang L, Wang Y, Su S, Xiang J. Catalytic effect of metal salts on deoxygenation and aromatization reaction during pressurized pyrolysis of corncob waste at mild temperatures. Energy 291:1-10(2024).
[30] Luo J, Sun K, Ma R, Sun S, Cui C, Huang H. CO2 enhanced continuous microwave pyrolysis of low-density polyethylene to produce high-quality products: Energy recovery balance and intrinsic mechanism exploration. Energy Conversion and Management 300:1-11(2024).
[31] Li J, Xu K, Yao X, Liu J. Investigation of biomass slow pyrolysis mechanisms based on the generation trends in pyrolysis products. Process Safety and Environmental Protection 183:327-338(2024).
[32] Shen W, He S, Mu M, Cao B, Wang S, Naqvi SR, Hanelt D, Abomohra A. A comprehensive review on the intricate processes involved in algae pyrolysis mechanism and possible migration of undesirable chemical elements. Journal of Analytical and Applied Pyrolysis 177:1-12(2024).
[33] Wang K, Shan T, Li B, Zheng Y, Xu H, Wang C, Tian X. Study on pyrolysis characteristics, kinetics and thermodynamics of waste tires catalytic pyrolysis with low-cost catalysts. Fuel 356:1-17(2024).
[34] Li C, Zhang C, Zhang L, Gholizadeh M, Hu X. Catalytic pyrolysis of tire waste: Impacts of biochar catalyst on product evolution. Waste Management 116:9-21(2020).
