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Biomass Processing for Biofuels, Bioenergy and Chemicals
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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.
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Keywords
- acclimatization
- alternative fuel
- anaerobic digestion
- anaerobic treatment
- antioxidant
- base-catalyzed transesterification
- bio-jet fuel
- biochar
- Biodiesel
- biodiesel production
- bioenergy
- bioethanol
- biofuel
- biogas
- Biomass
- biomass pretreatment
- black soldier fly larvae (BSFL)
- Box-Behnken design
- butylated hydroxyanisole
- co-combustion
- coffee mucilage
- combustion
- combustion characteristics
- compression ratio
- concentration polarization
- cow manure
- crude glycerol
- crude oil
- dark fermentation
- diesel
- dimethyl carbonate
- direct carbon fuel cell
- draw solution
- drop-in fuel
- emission
- energy yield
- Environment
- enzymatic digestibility
- extrusion
- FAME yield
- fatty acid methyl ester
- fatty acid methyl ester (FAME)
- fatty acid methyl esters
- feed solution
- Fermentation
- forward osmosis
- Fourier transform infrared spectroscopy
- free fatty acid
- free fatty acids
- gasification
- GCI
- glycerol carbonate
- hardwood
- hydrodeoxygenation
- Hydrogen
- injection strategies
- instar
- intake temperature
- kinetic study
- lignocellulose
- Lipid
- Lipids
- membrane fouling
- mesophilic
- Microwave
- microwave irradiation
- nano-additives
- nano-catalysts
- nanomagnetic catalyst
- Nanotechnology
- non-edible oil
- operating conditions
- organic wastes
- osmotic membrane
- oxidation stability
- palm oil mill effluent
- physico-chemical properties
- post-treatment
- potato peels
- power density
- power generation
- pre-treatment
- pressure-retarded osmosis
- pretreatment
- pyrolysis
- Rancimat method
- reaction kinetics
- renewable energy
- Response Surface
- Rhus typhina biodiesel
- rice husk
- rice straw
- rubber seed oil
- sewage sludge
- single-pellet combustion
- subcritical methanol
- synergistic effect
- technology development
- tert-butylhydroquinone
- thermogravimetric analysis
- thermophilic
- torrefaction
- triacylglycerides
- Vacuum
- viscosity
- waste
Links
DOI: 10.3390/books978-3-03928-910-3Editions
