Reprint

Biomass Processing for Biofuels, Bioenergy and Chemicals

Edited by
May 2020
428 pages
  • ISBN978-3-03928-909-7 (Paperback)
  • ISBN978-3-03928-910-3 (PDF)

This is a Reprint of the Special Issue Biomass Processing for Biofuels, Bioenergy and Chemicals that was published in

Chemistry & Materials Science
Engineering
Environmental & Earth Sciences
Physical Sciences
Summary
Biomass can be used to produce renewable electricity, thermal energy, transportation fuels (biofuels), and high-value functional chemicals. As an energy source, biomass can be used either directly via combustion to produce heat or indirectly after it is converted to one of many forms of bioenergy and biofuel via thermochemical or biochemical pathways. The conversion of biomass can be achieved using various advanced methods, which are broadly classified into thermochemical conversion, biochemical conversion, electrochemical conversion, and so on. Advanced development technologies and processes are able to convert biomass into alternative energy sources in solid (e.g., charcoal, biochar, and RDF), liquid (biodiesel, algae biofuel, bioethanol, and pyrolysis and liquefaction bio-oils), and gaseous (e.g., biogas, syngas, and biohydrogen) forms. Because of the merits of biomass energy for environmental sustainability, biofuel and bioenergy technologies play a crucial role in renewable energy development and the replacement of chemicals by highly functional biomass. This book provides a comprehensive overview and in-depth technical research addressing recent progress in biomass conversion processes. It also covers studies on advanced techniques and methods for bioenergy and biofuel production.
Format
  • Paperback
License and Copyright
© 2020 by the authors; CC BY-NC-ND license
Keywords
lignocellulose; pretreatment; hardwood; extrusion; enzymatic digestibility; bioethanol; renewable energy; biofuel; environment; technology development; co-combustion; sewage sludge; thermogravimetric analysis; Fourier transform infrared spectroscopy; synergistic effect; single-pellet combustion; biodiesel; fatty acid methyl ester; free fatty acids; oxidation stability; antioxidant; hydrogen; coffee mucilage; organic wastes; dark fermentation; anaerobic digestion; biodiesel; bio-jet fuel; triacylglycerides; Fatty Acid Methyl Ester; lipids; hydrodeoxygenation; drop-in fuel; rubber seed oil; biodiesel production; nanomagnetic catalyst; subcritical methanol; FAME yield; Box-Behnken design; GCI; biodiesel; diesel; combustion; emission; renewable energy; microwave; free fatty acid; crude oil; renewable energy; biomass; waste; black soldier fly larvae (BSFL); instar; lipid; fatty acid methyl ester (FAME); fermentation; Rancimat method; butylated hydroxyanisole; tert-butylhydroquinone; fatty acid methyl esters; viscosity; response surface; anaerobic treatment; biogas; kinetic study; potato peels; cow manure; thermophilic; mesophilic; palm oil mill effluent; acclimatization; direct carbon fuel cell; biochar; pyrolysis; power density; pre-treatment; post-treatment; combustion characteristics; injection strategies; compression ratio; intake temperature; torrefaction; vacuum; biomass pretreatment; bioenergy; energy yield; biochar; rice straw; rice husk; power generation; gasification; alternative fuel; Rhus typhina biodiesel; non-edible oil; base-catalyzed transesterification; Physico-chemical properties; concentration polarization; draw solution; feed solution; forward osmosis; pressure-retarded osmosis; operating conditions; membrane fouling; osmotic membrane; bioenergy; biofuel; nanotechnology; nano-catalysts; nano-additives; crude glycerol; glycerol carbonate; dimethyl carbonate; microwave irradiation; reaction kinetics