05090nam 2201225z- 450 991055730710332120231214133634.0(CKB)5400000000042785(oapen)https://directory.doabooks.org/handle/20.500.12854/77050(EXLCZ)99540000000004278520202201d2021 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierLignocellulosic BiomassBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20211 electronic resource (312 p.)3-0365-2475-4 3-0365-2474-6 Recently, there has been a growing awareness of the need to make better use of natural resources. Hence, the utilization of biomass has led to so-called biorefinery, consisting of the fractionation or separation of the different components of the lignocellulosic materials in order to achieve a total utilization of the same, and not only of the cellulosic fraction for paper production. The use of plant biomass as a basic raw material implies a shift from an economy based on the exploitation of non-renewable fossil fuels, with limited reserves or with regeneration cycles far below the rates of exploitation, to a bioeconomy based on the use of renewable organic natural resources, with balanced regeneration and extraction cycles. To make this change, profound readjustments in existing technologies are necessary, as well as the application of new approaches in research, development, and production."Biorefinery" is the term used to describe the technology for the fractionation of plant biomass into energy, chemicals, and consumer goods. The future generation of biorefinery will include treatments, leading to high-value-added compounds. The use of green chemistry technologies and principles in biorefineries, such as solvent and reagent recovery and the minimization of effluent and gas emissions, is essential to define an economically and environmentally sustainable process.In particular, the biorefinery of lignocellulosic materials to produce biofuels, chemicals and materials is presented as a solid alternative to the current petrochemical platform and a possible solution to the accumulation of greenhouse gases.Research & information: generalbicssclignocellulosic biomasssolid-state fermentationenzymatic hydrolysisaerated bioreactorAspergillus oryzaeligninlignocellulosearomaticsbiobasedepoxyfatty acidbiopolymersbiobased materialsbiorenewablebio-based filament3D printingsugarcane bagasse pulpbarley strawcompositeflexural strengthbiobased polyethylenenanocelluloseβ-cyclodextrincryogelsfilmsbiomaterialscellulosedialdehyde celluloseorganosilane chemistry29Si NMRsolid state NMRsilanizationlignocellulose valorization'lignin-first'reductive catalytic fractionationlignocellulose nanofibershorticultural residuespaperboardrecyclingbiosurfactantsenzymatic saccharificationfermentationquinoa saponinssteam-pretreated sprucelignocellulosic materialxylosefurfuraliron chloridemicrowave reactorbiorefineryelectrosynthesisbiomasscarbohydratesaccharideselectro-oxidationelectroreductionresidueagro-industryhigh-value productsbananatorrefactionJerusalem artichokebiofuelenergy cropsagiculturemicro-fibrillated celluloseformaldehyde adhesiveswood-based panelskraft ligninadsorbent materialcopper adsorptionH2S adsorptionH2S removalResearch & information: generalRodríguez Pascual Alejandroedt1302974Espinosa Víctor EduardoedtRodríguez Pascual AlejandroothEspinosa Víctor EduardoothBOOK9910557307103321Lignocellulosic Biomass3026792UNINA