This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Zhou, H., et al. (2014). An overview of characteristics of municipal solid waste fuel in China: physical, chemical composition and heating value. Renewable and sustainable energy reviews. 36, 107–122.ZhouH.2014An overview of characteristics of municipal solid waste fuel in China: physical, chemical composition and heating value3610712210.1016/j.rser.2014.04.024Search in Google Scholar
Pan, A., L. Yu, and Q. Yang (2019). Characteristics and forecasting of municipal solid waste generation in China. Sustainability, 11(5), 1433.PanA.YuL.YangQ.2019Characteristics and forecasting of municipal solid waste generation in China115143310.3390/su11051433Search in Google Scholar
Mian, M.M., et al. (2017). Municipal solid waste management in China: a comparative analysis. Journal of material cycles and waste management, 19(3), 1127–1135.MianM.M.2017Municipal solid waste management in China: a comparative analysis1931127113510.1007/s10163-016-0509-9Search in Google Scholar
Ji, G., et al. (2017). Enhanced hydrogen production from sawdust decomposition using hybrid-functional Ni-CaO-Ca2SiO4 materials. Environmental Science & Technology, 51(19), 11484–11492.JiG.2017Enhanced hydrogen production from sawdust decomposition using hybrid-functional Ni-CaO-Ca2SiO4 materials5119114841149210.1021/acs.est.7b03481Search in Google Scholar
Raheem, A., et al. (2018). Catalytic gasification of algal biomass for hydrogen-rich gas production: parametric optimization via central composite design. Energy Conversion and Management, 158, 235–245.RaheemA.2018Catalytic gasification of algal biomass for hydrogen-rich gas production: parametric optimization via central composite design15823524510.1016/j.enconman.2017.12.041Search in Google Scholar
Rada, E.C., et al. (2018). Dioxin contamination after a hypothetical accidental fire in baled municipal solid waste storage. environment, 17, 21.RadaE.C.2018Dioxin contamination after a hypothetical accidental fire in baled municipal solid waste storage172110.37358/RC.18.4.6245Search in Google Scholar
Khandelwal, H., et al. (2019). Application of life cycle assessment in municipal solid waste management: A worldwide critical review. Journal of Cleaner Production, 209, 630–654.KhandelwalH.2019Application of life cycle assessment in municipal solid waste management: A worldwide critical review20963065410.1016/j.jclepro.2018.10.233Search in Google Scholar
Cocarta, D., et al. (2009). A contribution for a correct vision of health impact from municipal solid waste treatments. Environmental technology, 30(9), 963–968.CocartaD.2009A contribution for a correct vision of health impact from municipal solid waste treatments30996396810.1080/09593330902989958Search in Google Scholar
Giusti, L. (2009). A review of waste management practices and their impact on human health. Waste management, 29(8), 2227–2239.GiustiL.2009A review of waste management practices and their impact on human health2982227223910.1016/j.wasman.2009.03.028Search in Google Scholar
Kanchanabhan, T., et al. (2011). Application of geographical information system (GIS) in optimisation of waste collection for Alandur Municipality in South Chennai, India. International Journal of Environment and Waste Management, 7(3–4), 395–410.KanchanabhanT.2011Application of geographical information system (GIS) in optimisation of waste collection for Alandur Municipality in South Chennai, India73–439541010.1504/IJEWM.2011.039478Search in Google Scholar
Young, G.C. (2010). Municipal solid waste to energy conversion processes: economic, technical, and renewable comparisons. John Wiley & Sons.YoungG.C.2010John Wiley & Sons10.1002/9780470608616Search in Google Scholar
McGowan, T. (2010). Municipal Solid Waste to Energy Conversion Processes: Economic, Technical and Renewable Comparisons. Chemical Engineering. 117(12), 8–10.McGowanT.2010Municipal Solid Waste to Energy Conversion Processes: Economic, Technical and Renewable Comparisons11712810Search in Google Scholar
Chen, L., et al. (2018). Co-pyrolysis kinetics and behaviors of kitchen waste and chlorella vulgaris using thermogravimetric analyzer and fixed bed reactor. Energy Conversion and Management, 165, 45–52.ChenL.2018Co-pyrolysis kinetics and behaviors of kitchen waste and chlorella vulgaris using thermogravimetric analyzer and fixed bed reactor165455210.1016/j.enconman.2018.03.042Search in Google Scholar
Van Nguyen, Q., et al. (2021). Co-pyrolysis of coffee-grounds and waste polystyrene foam: Synergistic effect and product characteristics analysis. 292, 120375.Van NguyenQ.202129212037510.1016/j.fuel.2021.120375Search in Google Scholar
Lopez, G., et al. (2017). Thermochemical routes for the valorization of waste polyolefinic plastics to produce fuels and chemicals. A review. Renewable and Sustainable Energy Reviews. 73, 346–368.LopezG.2017Thermochemical routes for the valorization of waste polyolefinic plastics to produce fuels and chemicals. A review7334636810.1016/j.rser.2017.01.142Search in Google Scholar
Lopez, G., et al. (2018). Recent advances in the gasification of waste plastics. A critical overview. Renewable and Sustainable Energy Reviews, 82, 576–596.LopezG.2018Recent advances in the gasification of waste plastics. A critical overview8257659610.1016/j.rser.2017.09.032Search in Google Scholar
Plastics. Plastics – the Facts 2016: An Analysis of European Plastics Production, demand and waste data. Brussels – Belgium. 2021 [cited 2020 August 17]; Available from: https://plasticseurope.org/wp-content/uploads/2021/10/2016-Plastic-the-facts.pdf.2021[cited 2020 August 17]; Available from: https://plasticseurope.org/wp-content/uploads/2021/10/2016-Plastic-the-facts.pdf.Search in Google Scholar
Kai, X., et al. (2019). TG-FTIR-MS study of synergistic effects during co-pyrolysis of corn stalk and high-density polyethylene (HDPE). Energy Conversion and Management, 181, 202–213.KaiX.2019TG-FTIR-MS study of synergistic effects during co-pyrolysis of corn stalk and high-density polyethylene (HDPE)18120221310.1016/j.enconman.2018.11.065Search in Google Scholar
Sharuddin, S.D.A., et al. (2016). A review on pyrolysis of plastic wastes. Energy conversion and management, 115, 308–326.SharuddinS.D.A.2016A review on pyrolysis of plastic wastes11530832610.1016/j.enconman.2016.02.037Search in Google Scholar
Kunwar, B., et al. (2016). Plastics to fuel: a review. Renewable and Sustainable Energy Reviews. 54, 421–428.KunwarB.2016Plastics to fuel: a review5442142810.1016/j.rser.2015.10.015Search in Google Scholar
Abnisa, F., et al. (2013). Co-pyrolysis of palm shell and polystyrene waste mixtures to synthesis liquid fuel. Fuel. 108, 311–318.AbnisaF.2013Co-pyrolysis of palm shell and polystyrene waste mixtures to synthesis liquid fuel10831131810.1016/j.fuel.2013.02.013Search in Google Scholar
Brebu, M., et al. (2010). Co-pyrolysis of pine cone with synthetic polymers. Fuel. 89(8), 1911–1918.BrebuM.2010Co-pyrolysis of pine cone with synthetic polymers8981911191810.1016/j.fuel.2010.01.029Search in Google Scholar
Özsin, G. and A.E. Pütün (2017). Insights into pyrolysis and co-pyrolysis of biomass and polystyrene: Thermochemical behaviors, kinetics and evolved gas analysis. Energy Conversion and Management, 149, 675–685.ÖzsinG.PütünA.E.2017Insights into pyrolysis and co-pyrolysis of biomass and polystyrene: Thermochemical behaviors, kinetics and evolved gas analysis14967568510.1016/j.enconman.2017.07.059Search in Google Scholar
Liu, Y., J. Qian, and J. Wang (2000). Pyrolysis of polystyrene waste in a fluidized-bed reactor to obtain styrene monomer and gasoline fraction. Fuel Processing Technology, 63(1), 45–55.LiuY.QianJ.WangJ.2000Pyrolysis of polystyrene waste in a fluidized-bed reactor to obtain styrene monomer and gasoline fraction631455510.1016/S0378-3820(99)00066-1Search in Google Scholar
Jin, Y. (2002). Study on MSW combustion characteristics and a new CFB incineration technology. Hangzhou: Zhejiang University.JinY.2002HangzhouZhejiang UniversitySearch in Google Scholar
Luo, S., et al. (2010). Effect of particle size on pyrolysis of single-component municipal solid waste in fixed bed reactor. International journal of hydrogen energy. 35(1), 93–97.LuoS.2010Effect of particle size on pyrolysis of single-component municipal solid waste in fixed bed reactor351939710.1016/j.ijhydene.2009.10.048Search in Google Scholar
Zhang, Q., et al. (2012). Gasification of municipal solid waste in the Plasma Gasification Melting process. Applied Energy. 90(1), 106–112.ZhangQ.2012Gasification of municipal solid waste in the Plasma Gasification Melting process90110611210.1016/j.apenergy.2011.01.041Search in Google Scholar
Lopez-Velazquez, M., et al. (2013). Pyrolysis of orange waste: a thermo-kinetic study. Journal of Analytical and Applied Pyrolysis, 99, 170–177.Lopez-VelazquezM.2013Pyrolysis of orange waste: a thermo-kinetic study9917017710.1016/j.jaap.2012.09.016Search in Google Scholar
Chen, S., et al. (2015). TGA pyrolysis and gasification of combustible municipal solid waste. Journal of the energy institute, 88(3), 332–343.ChenS.2015TGA pyrolysis and gasification of combustible municipal solid waste88333234310.1016/j.joei.2014.07.007Search in Google Scholar
Meng, A., et al. (2015). Pyrolysis and gasification of typical components in wastes with macro-TGA. Waste management, 46, 247–256.MengA.2015Pyrolysis and gasification of typical components in wastes with macro-TGA4624725610.1016/j.wasman.2015.08.025Search in Google Scholar
Zheng, J., et al. (2009). Pyrolysis characteristics of organic components of municipal solid waste at high heating rates. Waste Management, 29(3), 1089–1094.ZhengJ.2009Pyrolysis characteristics of organic components of municipal solid waste at high heating rates2931089109410.1016/j.wasman.2008.06.034Search in Google Scholar
Dawei, A., et al. (2006). Low temperature pyrolysis of municipal solid waste: influence of pyrolysis temperature on the characteristics of solid fuel. International journal of energy research, 30(5), 349–357.DaweiA.2006Low temperature pyrolysis of municipal solid waste: influence of pyrolysis temperature on the characteristics of solid fuel30534935710.1002/er.1152Search in Google Scholar
Singh, S., C. Wu, and P.T. Williams (2012). Pyrolysis of waste materials using TGA-MS and TGA-FTIR as complementary characterisation techniques. Journal of Analytical and Applied Pyrolysis, 94, 99–107.SinghS.WuC.WilliamsP.T.2012Pyrolysis of waste materials using TGA-MS and TGA-FTIR as complementary characterisation techniques949910710.1016/j.jaap.2011.11.011Search in Google Scholar
Zhao, M., et al. (2019). Iso-conversional kinetics of low-lipid micro-algae gasification by air. Journal of Cleaner Production, 207, 618–629.ZhaoM.2019Iso-conversional kinetics of low-lipid micro-algae gasification by air20761862910.1016/j.jclepro.2018.10.040Search in Google Scholar
De Caprariis, B., et al. (2012). Double-Gaussian distributed activation energy model for coal devolatilization. Energy & Fuels. 26(10), 6153–6159.De CaprariisB.2012Double-Gaussian distributed activation energy model for coal devolatilization26106153615910.1021/ef301092rSearch in Google Scholar
Sørum, L., M. Grønli, and J. Hustad (2001). Pyrolysis characteristics and kinetics of municipal solid wastes. Fuel. 80(9), 1217–1227.SørumL.GrønliM.HustadJ.2001Pyrolysis characteristics and kinetics of municipal solid wastes8091217122710.1016/S0016-2361(00)00218-0Search in Google Scholar
Gunasee, S.D., et al. (2016). Pyrolysis and combustion of municipal solid wastes: Evaluation of synergistic effects using TGA-MS. Journal of Analytical and Applied Pyrolysis, 121, 50–61.GunaseeS.D.2016Pyrolysis and combustion of municipal solid wastes: Evaluation of synergistic effects using TGA-MS121506110.1016/j.jaap.2016.07.001Search in Google Scholar
CE. Research helps Europe advance towards circular economy. 2021 [cited 2021 August 12]; Available from: https://ec.europa.eu/jrc/en/news/research-helps-europe-advance-towards-circular-economy.2021[cited 2021 August 12]; Available from: https://ec.europa.eu/jrc/en/news/research-helps-europe-advance-towards-circular-economy.Search in Google Scholar
Yong, Z.J., et al. (2019). Sustainable waste-to-energy development in Malaysia: Appraisal of environmental, financial, and public issues related with energy recovery from municipal solid waste. Processes, 7(10), 676.YongZ.J.2019Sustainable waste-to-energy development in Malaysia: Appraisal of environmental, financial, and public issues related with energy recovery from municipal solid waste71067610.3390/pr7100676Search in Google Scholar
UN. United Nations Economic and Social Commissions (UNESCAP) (2016). Visualization of Interlinkages for SDG 7; UNESCAP: New York, NY, USA. (accessed on 20 December 2021). Available. 2021; Available from: https://www.unescap.org/sites/default/files/Visualisation%20of%20interlinkages%20for%20SDG%207.pdf.UN. United Nations Economic and Social Commissions (UNESCAP)2016UNESCAPNew York, NY, USA(accessed on 20 December 2021). Available. 2021; Available from: https://www.unescap.org/sites/default/files/Visualisation%20of%20interlinkages%20for%20SDG%207.pdf.Search in Google Scholar
UN. GOAL 7: Affordable ad Clean Energy; UN Environment: Nairobi, Kenyan, 2019. 2021 [cited 2021 December 25]; Available from: https://www.unep.org/explore-topics/sustainable-development-goals/why-do-sustainable-development-goals-matter/goal-7.UN. GOAL 7: Affordable ad Clean Energy20192021 [cited 2021 December 25]; Available from: https://www.unep.org/explore-topics/sustainable-development-goals/why-do-sustainable-development-goals-matter/goal-7.Search in Google Scholar
Zhao, M., N.H. Florin, and A.T. Harris (2009). The influence of supported Ni catalysts on the product gas distribution and H2 yield during cellulose pyrolysis. Applied Catalysis B: Environmental. 92(1–2), 185–193.ZhaoM.FlorinN.H.HarrisA.T.2009The influence of supported Ni catalysts on the product gas distribution and H2 yield during cellulose pyrolysis921–218519310.1016/j.apcatb.2009.07.011Search in Google Scholar
Zhao, M., N.H. Florin, and A.T. Harris (2010). Mesoporous supported cobalt catalysts for enhanced hydrogen production during cellulose decomposition. Applied Catalysis B: Environmental, 97(1–2), 142–150.ZhaoM.FlorinN.H.HarrisA.T.2010Mesoporous supported cobalt catalysts for enhanced hydrogen production during cellulose decomposition971–214215010.1016/j.apcatb.2010.03.034Search in Google Scholar
Abd Aziz, M.F.S. and Z.A. Zakaria (2018). Oil Palm Biomass and Its Kinetic Transformation Properties, in Biosynthetic Technology and Environmental Challenges. Springer, 73–87.Abd AzizM.F.S.ZakariaZ.A.2018Oil Palm Biomass and Its Kinetic Transformation PropertiesinSpringer738710.1007/978-981-10-7434-9_5Search in Google Scholar
Mishra, R.K. and K. Mohanty (2018). Pyrolysis kinetics and thermal behavior of waste sawdust biomass using thermogravimetric analysis. Bioresource technology, 251, 63–74.MishraR.K.MohantyK.2018Pyrolysis kinetics and thermal behavior of waste sawdust biomass using thermogravimetric analysis251637410.1016/j.biortech.2017.12.029Search in Google Scholar
Zhang, Q., et al. (2017). Experimental study on copyrolysis and gasification of biomass with deoiled asphalt. Energy, 134, 301–310.ZhangQ.2017Experimental study on copyrolysis and gasification of biomass with deoiled asphalt13430131010.1016/j.energy.2017.05.157Search in Google Scholar
Özsin, G. and A.E. Pütün (2019). TGA/MS/FT-IR study for kinetic evaluation and evolved gas analysis of a biomass/PVC co-pyrolysis process. Energy conversion and management, 182, 143–153.ÖzsinG.PütünA.E.2019TGA/MS/FT-IR study for kinetic evaluation and evolved gas analysis of a biomass/PVC co-pyrolysis process18214315310.1016/j.enconman.2018.12.060Search in Google Scholar
Huang, Z., Q.-q. Ye, and L.-j. Teng (2015). A comparison study on thermal decomposition behavior of poly (l-lactide) with different kinetic models. Journal of Thermal Analysis and Calorimetry, 119(3).HuangZ.YeQ.-q.TengL.-j.2015A comparison study on thermal decomposition behavior of poly (l-lactide) with different kinetic models119310.1007/s10973-014-4311-4Search in Google Scholar
Jain, A.A., A. Mehra, and V.V. Ranade (2016). Processing of TGA data: Analysis of isoconversional and model fitting methods. Fuel, 165, 490–498.JainA.A.MehraA.RanadeV.V.2016Processing of TGA data: Analysis of isoconversional and model fitting methods16549049810.1016/j.fuel.2015.10.042Search in Google Scholar
Ali, M., et al. (2018). The effect of hydrolysis on combustion characteristics of sewage sludge and leaching behavior of heavy metals. Environmental technology, 39(20), 2632–2640.AliM.2018The effect of hydrolysis on combustion characteristics of sewage sludge and leaching behavior of heavy metals39202632264010.1080/09593330.2017.1363296Search in Google Scholar
Zhou, H., et al. (2015). Thermogravimetric characteristics of typical municipal solid waste fractions during co-pyrolysis. Waste management, 38, 194–200.ZhouH.2015Thermogravimetric characteristics of typical municipal solid waste fractions during co-pyrolysis3819420010.1016/j.wasman.2014.09.027Search in Google Scholar
Figueira, C.E., P.F. Moreira Jr, and R. (2015). Giudici, Thermogravimetric analysis of the gasification of microalgae Chlorella vulgaris. Bio resource technology, 198, 717–724.FigueiraC.E.MoreiraP.F.JrR.2015Giudici, Thermogravimetric analysis of the gasification of microalgae Chlorella vulgaris19871772410.1016/j.biortech.2015.09.059Search in Google Scholar
López-González, D., et al. (2014). Comparison of the steam gasification performance of three species of microalgae by thermogravimetric–mass spectrometric analysis. Fuel, 134, 1–10.López-GonzálezD.2014Comparison of the steam gasification performance of three species of microalgae by thermogravimetric–mass spectrometric analysis13411010.1016/j.fuel.2014.05.051Search in Google Scholar
Ridout, A.J., M. Carrier, and J. Görgens (2015). Fast pyrolysis of low and high ash paper waste sludge: Influence of reactor temperature and pellet size. Journal of analytical and applied pyrolysis, 111, 64–75.RidoutA.J.CarrierM.GörgensJ.2015Fast pyrolysis of low and high ash paper waste sludge: Influence of reactor temperature and pellet size111647510.1016/j.jaap.2014.12.010Search in Google Scholar
Garcia-Maraver, A., et al. (2015). Determination and comparison of combustion kinetics parameters of agricultural biomass from olive trees. Renewable Energy, 83, 897–904.Garcia-MaraverA.2015Determination and comparison of combustion kinetics parameters of agricultural biomass from olive trees8389790410.1016/j.renene.2015.05.049Search in Google Scholar
Cheng, K., W.T. Winter, and A.J. Stipanovic (2012). A modulated-TGA approach to the kinetics of lignocellulosic biomass pyrolysis/combustion. Polymer degradation and stability, 97(9), 1606–1615.ChengK.WinterW.T.StipanovicA.J.2012A modulated-TGA approach to the kinetics of lignocellulosic biomass pyrolysis/combustion9791606161510.1016/j.polymdegradstab.2012.06.027Search in Google Scholar
Khoso, S., Ansari, A. A., Wagan, F. H., (2014). Investigative constrution of buildings using baked clay post reinforced beam panels. Journal of Architecture Civil Engineering Environment ACEE, 7(4), 57–66. ISSN: 1899-0142KhosoS.AnsariA. A.WaganF. H.2014Investigative constrution of buildings using baked clay post reinforced beam panels745766ISSN: 1899-0142Search in Google Scholar
Khoso, S., Naqash, M. T., Sher, S., & Saeed, Z. (2018). An experimental study on fiberly reinforced concrete using polypropylene fibre with virgin and recycled road aggregate. Journal of Architecture Civil Engineering Environment, 11, 73–80.KhosoS.NaqashM. T.SherS.SaeedZ.2018An experimental study on fiberly reinforced concrete using polypropylene fibre with virgin and recycled road aggregate11738010.21307/acee-2018-007Search in Google Scholar
Khoso, S., Raad, J., & Parvin, A. (2019). Experimental investigation on the properties of recycled concrete using hybrid fibers. Open Journal of Composite Materials, 9(02), 183.KhosoS.RaadJ.ParvinA.2019Experimental investigation on the properties of recycled concrete using hybrid fibers90218310.4236/ojcm.2019.92009Search in Google Scholar
A Soltani, S Khoso, MA Keerio, A Formisano, (2019) “Assessment of Physical and Mechanical Properties of Concrete Produced from Various Portland Cement Brands” Open Journal of Composite Materials 9(04), 327.SoltaniAKhosoSKeerioMAFormisanoA2019“Assessment of Physical and Mechanical Properties of Concrete Produced from Various Portland Cement Brands”90432710.4236/ojcm.2019.94020Search in Google Scholar