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Erschienen in:
Microbial Valorization of Coir Pith for Development of Compost and Bioethanol Production Kapitel lesen Erstes Kapitel lesen

2021 | OriginalPaper | Buchkapitel

11. Agricultural Waste Valorization: An Energy Production Perspective

verfasst von : Shiv Prasad, Dheeraj Rathore, Anoop Singh

Erschienen in: Bio-valorization of Waste

Verlag: Springer Singapore

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Abstract

The energy security, utilization of surplus agricultural waste, and environmental concerns lead to explore the opportunities for valorization of surplus agricultural waste. The agricultural waste is rich in lignocellulose, which can be converted into various forms of energy like ethanol, methane, hydrogen, etc. by adopting different technologies. Therefore, the available surplus agricultural residues can be utilized for sustainable energy production. This will not only produce energy from waste but also save the environment from emissions due to its disposal. The sustainable approach for valorization of agricultural waste can be found by employing the various modellings like life cycle assessment (LCA), life cycle costing (LCC), net energy ratio (NER), techno-economic assessment (TEA), etc.

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Vorheriges Kapitel Recent Advances in Wastewater Sludge Valorization
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Literatur
Amani T, Nosrati M, Sreekrishnan TR (2010) Anaerobic digestion from the viewpoint of microbiological, chemical, and operational aspects-a review. Environ Rev 18:255–278CrossRef
Batidzirai B, Mignot APR, Schakel WB, Junginger HM, Faaij APC (2013) Biomass torrefaction technology: techno-economic status and future prospects. Energy 62:196–214CrossRef
Bosmans A, Vanderreydt I, Geysen D, Helsen L (2013) The crucial role of waste to- energy technologies in enhanced landfill mining: a technology review. J Clean Prod 55:10–23CrossRef
Chambers A (2003) Renewable energy in non-technical language. PennWell Books, Houston
Clini C, Musu I, Gullino ML (2008) Sustainable development and environmental management: experiences and case studies. Springer, Berlin, pp 228–229CrossRef
Deppenmeir U, Müller V, Gottschalk G (1996) Pathways of energy conservation in methanogenic archaea. Archaea Microbiol 165:149–163CrossRef
Duque-Acevedo M, Belmonte-Urena LJ, Cortes-García FJ, Camacho-Ferre F (2020) Agricultural waste: review of the evolution, approaches and perspectives on alternative uses. Glob Ecol Conserv 22:e00902CrossRef
FAO (2018) Food and agriculture organization of the United Nations. In: World food and agriculture statistical pocketbook 2018. FAO, Rome
Garcia JL, Patel BKC, Ollivier B (2000) Taxonomic phylogenetic and ecological diversity of methanogenetic Archaea. Anaerobe 6:205–226CrossRef
Gasafi E, Reinecke MY, Kruse A, Schebek L (2008) Economic analysis of sewage sludge gasification in supercritical water for hydrogen production. Biomass and Bioenergy 32(12):1085–1096
Gujer W, Zehnder AJB (1983) Conversion processes in anaerobic digestion. Water Sci Technol 15:127–167CrossRef
Hsieh W, Chen R, Wu T, Lin T (2002) Engine performance and pollutant emission of an SI engine using ethanol-gasoline blended fuels. Atmos Environ 36:403–410CrossRef
Insam H, Franke-Whittle I, Goberna M (2010) Microbes in aerobic and anaerobic waste treatment. In: Insam H, Franke-Whittle I, Goberna M (eds) Microbes at work. Springer, Berlin, pp 1–34CrossRef
Juneja A, Murthy GS (2017) Evaluating the potential of renewable diesel production from algae cultured on wastewater: techno-economic analysis and life cycle assessment. AIMS Energy 5:239–257CrossRef
Li S, Yang X (2016) Biofuel production from food wastes. In: Luque R, CSK L, Wilson K, Clark J (eds) Handbook of biofuels production. Woodhead Publishing, Sawston, pp 617–653
Liu H, Ma X, Li L, Hu Z, Guo P, Jiang Y (2014) The catalytic pyrolysis of food waste by microwave heating. Bioresour Technol 166:45–50CrossRef
Medic D, Darr M, Shah A, Potter B, Zimmerman J (2012) Effects of torrefaction process parameters on biomass feedstock upgrading. Fuel 91:147–154CrossRef
Nandkumar N (2014) Plasma-the fourth state of matter. Int J Sci Technol Res 3(9):49–52
Onwudili JA, Lea-Langton AR, Ross AB, Williams PT (2013) Catalytic hydrothermal gasification of algae for hydrogen production: composition of reaction products and potential for nutrient recycling. Bioresour Technol 127:72–80CrossRef
Pham TPT, Kaushik R, Parshetti GK, Mahmood R, Balasubramanian R (2015) Food waste-to-energy conversion technologies: current status and future directions. Waste Manag 38:399–408CrossRef
Prasad S, Dhanya MS, Gupta N, Kumar A (2012) Biofuels from biomass: a sustainable alternative to energy and environment. Biochem Cell Arch 12(2):255–260
Prasad S, Kumar A, Muralikrishna KS (2014) Biofuels production: a sustainable solution to combat climate change. Indian J Agric Sci 84(12):1443–1452
Prasad S, Lata, Joshi HC (2009) Selection of efficient S. cerevisiae strain for ethanol production from Sorghum stalk juice. Curr Adv Agri Sci 1(2):70–73
Prasad S, Rathore D, Singh A (2017) Recent advances in biogas production. Chem Eng Process Tech 3(2):1038
Prasad S, Singh A, Joshi HC (2007) Ethanol as an alternative fuel from agricultural, industrial and urban residues. Resour Conserv Recycl 50(1):1–39
Prasad S, Singh A, Korres NE, Rathore D, Sevda S, Pant D (2020) Sustainable utilization of crop residues for energy generation: a life cycle assessment (LCA) perspective. Bioresour Technol 303:122964CrossRef
Prins MJ, Ptasinski KJ, Janssen FJJG (2006) More efficient biomass gasification via torrefaction. Energy 31(15):3458–3470CrossRef
Quinn JC, Davis R (2015) The potentials and challenges of algae based biofuels: a review of the techno-economic, life cycle, and resource assessment modeling. Bioresource Technol 184:444–452CrossRef
Sahoo J, Patil P, Verma A, Lodh A, Khanna N, Prasad R, Pandit S, Fosso-Kankeu E (2021) Biochemical aspects of syngas fermentation. In: Prasad R, Singh J, Kumar V, Upadhyay CP (eds) Recent developments in microbial technologies. Springer Nature, Singapore, pp 395–424
Scarlat N, Motola V, Dallemand JF, Monforti-Ferrario F, Linus M (2015) Evaluation of energy potential of municipal solid waste from African urban areas. Renew Sust Energ Rev 50:1269–1286CrossRef
Si B, Watson J, Aierzhati A, Yang L, Liu Z, Zhang Y (2019) Biohythane production of post-hydrothermal liquefaction wastewater: a comparison of two-stage fermentation and catalytic hydrothermal gasification. Bioresour Technol 274:335–342CrossRef
Tock JY, Lai CL, Lee KT, Tan KT, Bhatia S (2010) Banana biomass as a potential renewable energy resource: a Malaysian case study. Renew Sust Energ Rev 14(2):798–805CrossRef
UN-HABITAT (2010) Collection of municipal solid waste in developing countries. United Nations Human Settlements Programme (UN-HABITAT), Nairobi
Watson J, Wang T, Si B, Chen W-T, Aierzhati A, Zhang Y (2020) Valorization of hydrothermal liquefaction aqueous phase: pathways towards commercial viability. Prog Energy Combust Sci 77:100819CrossRef
Xu F, Li Y, Ge X, Yang L, Li Y (2018) Anaerobic digestion of food waste-challenges and opportunities. Bioresour Technol 247:1047–1058CrossRef
Metadaten
Titel
Agricultural Waste Valorization: An Energy Production Perspective
verfasst von
Shiv Prasad
Dheeraj Rathore
Anoop Singh
Copyright-Jahr
2021
Verlag
Springer Singapore
Buch
Bio-valorization of Waste

Print ISBN: 978-981-15-9695-7

Electronic ISBN: 978-981-15-9696-4

Copyright-Jahr: 2021

DOI
https://doi.org/10.1007/978-981-15-9696-4_11