03336nam 2200769z- 450 9910367741603321202102113-03921-915-4(CKB)4100000010106301(oapen)https://directory.doabooks.org/handle/20.500.12854/42792(oapen)doab42792(EXLCZ)99410000001010630120202102d2019 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierCatalytic Processes for The Valorisation of Biomass Derived MoleculesMDPI - Multidisciplinary Digital Publishing Institute20191 online resource (114 p.)3-03921-914-6 In the last decades, inedible lignocellulosic biomasses have attracted significant attention for being abundant resources that are not in competition with agricultural land or food production and, therefore, can be used as starting renewable material for the production of a wide variety of platform chemicals. The three main components of lignocellulosic biomasses are cellulose, hemicellulose and lignin, complex biopolymers that can be converted into a pool of platform molecules including sugars, polyols, alchols, ketons, ethers, acids and aromatics. Various technologies have been explored for their one-pot conversion into chemicals, fuels and materials. However, in order to develop new catalytic processes for the selective production of desired products, a complete understanding of the molecular aspects of the basic chemistry and reactivity of biomass derived molecules is still crucial. This Special Issue reports on recent progress and advances in the catalytic valorization of cellulose, hemicellulose and lignin model molecules promoted by novel heterogeneous systems for the production of energy, fuels and chemicals.aromatic ethersbio-insulating oilbio-oil upgradebioethanolbiomassBrønsted acids sitescatalytic transfer hydrogenolysis reactionscellulosechemical-loop reformingChilean natural zeolitesdesilicationDiels-AlderdimethylfuranfurfuralGC/MS characterizationglycerolglycidolH-donor moleculeshemicelluloseheterogeneous catalysishierarchical zeoliteshydrogenolysishydroisomerizationinsulating oilslevulinic acidligninlignocellulosic biomassesmetal ferritesn/apolyolsrenewable aromaticsrenewable p-xylenesolketalspinelssyngaszeoliteZSM-5Mauriello Francescoauth1301454Espro ClaudiaauthGalvagno SignorinoauthBOOK9910367741603321Catalytic Processes for The Valorisation of Biomass Derived Molecules3025867UNINA05472nam 22014653a 450 991036775250332120250203235436.09783039216314303921631710.3390/books978-3-03921-631-4(CKB)4100000010106192(oapen)https://directory.doabooks.org/handle/20.500.12854/43351(ScCtBLL)16045db5-e58e-4f21-82cf-0d6149195698(OCoLC)1163804461(oapen)doab43351(EXLCZ)99410000001010619220250203i20192019 uu engurmn|---annantxtrdacontentcrdamediacrrdacarrierClean Energy and Fuel (Hydrogen) StorageSesha Srinivasan, Elias StefanakosMDPI - Multidisciplinary Digital Publishing Institute2019Basel, Switzerland :MDPI,2019.1 electronic resource (278 p.)9783039216307 3039216309 Clean energy and fuel storage are often required for both stationary and automotive applications. Some of these clean energy and fuel storage technologies currently under extensive research and development include hydrogen storage, direct electric storage, mechanical energy storage, solar-thermal energy storage, electrochemical (batteries and supercapacitors), and thermochemical storage. The gravimetric and volumetric storage capacity, energy storage density, power output, operating temperature and pressure, cycle life, recyclability, and cost of clean energy or fuel storage are some of the factors that govern efficient energy and fuel storage technologies for potential deployment in energy harvesting (solar and wind farms) stations and onboard vehicular transportation. This Special Issue thus serves the need for promoting exploratory research and development on clean energy and fuel storage technologies while addressing their challenges to practical and sustainable infrastructures.History of engineering and technologybicsscMgH2vertically oriented graphenegas lossconcentrated solar power (CSP)complex hydridesPCM roofhydrogen storage systemsslagbubbles transportationdye-sensitized solar cellsundercoolingmethanogenesiselectrochemical energy storagehydrogen storageFischer–Tropschstate of charge estimatorgas turbine enginesimplified electrochemical modelhot summer and cold winter arearock permeabilityflutter instabilitycharge densitybindersalt cavern energy storagebattery energy storage systemcapacitanceLiNH2ball millingproduction rateleaching tubingquality function deployment (QFD)nanocatalystlab-scalethermal energy storage (TES)comprehensive incremental benefitlean direct injectionLi-ion batteriesseparatorfour-pointsalt cavernlow emissions combustionionic liquidcarbon materialsnanocomposite materialselectrical double layersrecovery factorthermochemical energy storageKlinkenberg methodflow-induced vibrationcathodeporous mediametal hydrideaquifer sizediffusionauxiliary services compensationwater invasionconjugate phase change heat transferheat transfer enhancementfailure mode and effect analysis (FMEA)magnetismcarbonate gas reservoirsequivalent loss of cycle lifeinternal and reverse external axial flowsthermal energy storagelithium-ion batteriesbacterial sulfate reductioncrystal growth ratesoptimal capacitygas storageenergy dischargeanodeAg nanoparticlesregeneratorhydrogen absorptionfreestanding TiO2 nanotube arraysmaterial scienceextended kalman filterreactive transport modelingsynthetic rock salt testinghydrogen energy storagelattice Boltzmann methoddynamic modelingbubbles burstPower to Liquidlarge-scale wind farmPHREEQCHistory of engineering and technologySrinivasan Sesha1296345Stefanakos EliasScCtBLLScCtBLLBOOK9910367752503321Clean Energy and Fuel (Hydrogen) Storage3024024UNINA