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Landfills throughout the world are contributing to the global warming problem. This is due to the existence of the most important greenhouse gases in landfill gas; namely, methane and carbon dioxide. Methane has a high potential for energy production and by utilizing the proper technology, large amounts of energy can be extracted from it. This paper deals with the estimation of methane emissions from the controlled municipal solid waste landfill of Mohammedia-Benslimane (MB) in Morocco. Methane emissions were calculated using the LandGEM method. In this research, the following parameters were evaluated: the amount of landfilled waste, the characteristics of the landfill and the composition of the landfilled waste, as well as the climatic conditions prevailing in the region. According to the LandGEM model, the total amount of methane generated from approximately 3.663 E+06 kg of municipal solid waste that will be buried of in the MB controlled landfill over 20 years,2012 to 2032, is 1.76 E+08 m3. For the year 2020, the estimated electrical energy production in the landfill is 1.78 E+07 kWh. Regarding the carbon footprint for this landfill, the landfilling of household solid waste at the MB landfill has resulted in a production of about 499,238,000 kg CO2e in 2020 since its opening in 2012, according to the LandGEM model. These huge amounts of greenhouse gas are related to the fact that the waste buried at this landfill is highly organic. By installing an efficient system to capture and flare the biogas generated in this landfill, the management of this landfill is actively contributing to the protection of the environment by mitigating greenhouse gas emissions, particularly methane.
Czasopismo
Rocznik
Tom
Strony
116--129
Opis fizyczny
Bibliogr. 17 poz., rys., tab.
Twórcy
autor
- Faculty of Science and Technology, Laboratory of Radiations Materials and Instrumentations, Hassan First University of Settat, Road to Casablanca Km 3.5, 26000, Settat, Morocco
autor
- Faculty of Science and Technology, Laboratory of Applied Chemistry and Environment, Hassan First University of Settat, Road to Casablanca Km 3.5, 26000, Settat, Morocco
autor
- Faculty of Science and Technology, Laboratory of Radiations Materials and Instrumentations, Hassan First University of Settat, Road to Casablanca Km 3.5, 26000, Settat, Morocco
Bibliografia
- 1. Abbasi S.A. 2018. The myth and the reality of energy recovery from municipal solid waste. Energy, Sustainability and Society, 8(1), 2–15.
- 2. Ayodele T.R., Ogunjuyigbe A.S.O., Alao Power M.A. 2017. Life cycle assessment of waste-to-energy (WtE) technologies for electricity generation using municipal solid waste in Nigeria. Applied Energy, 201, 200–2018.
- 3. Chofqi A., Younsi A., Lhadi E., Mania J., Mudry J., Veron A. 2004. Environmental impact of an urban landfill on a coastal aquifer (El Jadida, Morocco). Journal of African Earth Sciences, 39(3–5), 509–516.
- 4. Cudjoe D., Su Han M. 2021. Economic feasibility and environmental impact analysis of landfill gas to energy technology in African urban areas. Journal of Cleaner Production, 284, 125437.
- 5. Elmaghnougi I., Afilal Tribak A., Maatouki M. 2018. Assessment of leachates from uncontrolled landfill: Tangier case study. E3S Web of Conferences, 37, 4–13.
- 6. EPA USA. 2008. Background Information Document for Updating AP42 Section 2.4 for Estimating Emissions from Municipal Solid Waste Landfills. September (EPA/600/R-08-116), 249.
- 7. Fei F., Wena Z., De Clercqa D. 2019. Spatio-temporal estimation of landfill gas energy potential: A case study in China. Renewable and Sustainable Energy Reviews, 103(C), 217–226.
- 8. Haro K., Ouarma I., Sanogo O., Compaore A., Tubreoumya G.C., Nana B., Bere A., Koulidiati J. 2019. Assessment of the carbon footprint of a Non-Hazardous Waste Storage Facility (NWISH): Case of the waste treatment and recovery center (CTVD) in Polesgo (Ouagadougou). Journal de Physique de la SOAPHYS, 1(1), C19A5-1-C19A5-5. (in French)
- 9. Kumar A., Samadder S.R. 2017. A review on technological options of waste to energy for effective management of municipal solid waste. Waste Management, 69, 407–422.
- 10. Lattanzi I.E., Prata Filho D.A., Quelhas O.L.G. 2019. Modeling of biogas generation by applying CDM methodology for greenhouse gas emission reduction: case of the MTR Santa Maria Madalena landfill, RJ, Brazil. Systems & Management, 14(4), 483–491.
- 11. Naimi Y., Saghir M., Cherqaoui A., Chatre B. 2017. Energetic recovery of biomass in the region of Rabat, Morocco. International Journal of Hydrogen Energy, 42(2), 1396–1402.
- 12. Noor Z., Yusuf R, Abba A., Abu Hassan M., Mohd Din M. 2013. An overview for energy recovery from municipal solid wastes (MSW)in Malaysia scenario. Renewable and Sustainable Energy Reviews, 20, 378–384.
- 13. Park J., Tameda K., Higuchi S., Lee N. 2017. Estimation of the methane generation rate constant using a large-scale respirometer at a landfill site. Environmental Engineering Research, 22(4), 339–346.
- 14. Pillai J., Riverol C. 2018. Estimation of gas emission and derived electrical power generation from landfills. Trinidad and Tobago as study case. Sustainable Energy Technologies and Assessments, 29(October 2017), 139–146.
- 15. Plocoste T., Jacoby-Koaly S., Petit R., Roussas A. 2016. Estimation of Methane Emission from a Waste Dome in a Tropical Insular Area. International Journal of Waste Resources, 6(2), 1000211.
- 16. Saghir M., El Mahi Chbihi M., Tahiri M., Naimi Y. 2018. Estimated Production of Electrical Energy for the Controlled Landfill in Fez (Morocco) by the Land-GEM Model of US EPA. American Journal of Earth Science and Engineering, 1(2), 137–142
- 17. Tayyeba O., Olsson M., Brandt N. 2011. The best MSW treatment option by considering greenhouse gas emissions reduction: a case study in Georgia. Waste Management and Research, 29(8), 823–833.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-dad46cdb-25af-473a-89a5-970d7a1371b7