LEADER 04138nam  2200925z- 450 
001 9910404083103321
005 20240107232857.0
010   $a3-03928-836-9
035   $a(CKB)4100000011302307
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/40292
035   $a(EXLCZ)994100000011302307
100   $a20202102d2020      |y             0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aAdvances in Heterocatalysis by Nanomaterials
210   $cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 electronic resource (166 p.)
311   $a3-03928-835-0 
330   $aHeterogeneous catalysis played, plays, and will continue to play, a major key role in industrial processes for large-scale synthesis of commodity chemicals of global importance, and in catalytic systems that possess a critical role in energy generation and environmental protection approaches. As a result of the ongoing progress in materials science, nanotechnology, and characterizations, great advances have been achieved in heterogeneous catalysis by nanomaterials. Efficient approaches and advanced methods for the design of nano-structured composite materials (up to atomic level), subject to specific nano-morphologies with enhanced metal?metal and metal?support interactions favorable for catalysis (that enable fine-tuning of the critical properties of the designed catalysts), provide optimized catalysts with outstanding performances in numerous eco-friendly and cost-effective applications. Accordingly, great progress has been achieved involving, for example, emissions control, waste treatment, photocatalytic, bio-refinery, CO2 utilization, and fuel cells applications, as well as hydrocarbon processing for H2, added-value chemicals, and liquid fuels production. The themed Special Issue has succeeded in collecting 10 high-quality contributions that cover recent research progress in the field for a variety of applications (e.g., environment, energy, added-value chemicals/organics synthesis, and bio-transformation) declaring the prospect and importance of nanomaterials in all the directions of heterogeneous catalysis.
610   $aB-doped
610   $apolyoxymethylene dimethyl ethers
610   $aporous carbon
610   $aself-catalytic pyrolysis
610   $avisible light
610   $aheterostructure
610   $aoxygen vacancies
610   $aTiO2 nanotube
610   $athiadiazoles
610   $aethylidenethiosemicarbazides
610   $aadsorption
610   $adimethoxymethane
610   $anano-biocatalyst
610   $aheterogeneous catalysis
610   $abio-catalysis
610   $aH2 evolution
610   $acarbon cuboids
610   $atrioxymethylene
610   $a?-glucosidase
610   $ametal-organic frameworks
610   $aBrønsted acid sites
610   $ahybrid
610   $aMXene
610   $aoleuropein
610   $aRhodamine B
610   $aantibiotics
610   $amaleic anhydride
610   $aoxygen evolution reaction
610   $aphotocatalyst
610   $a2-methyl-3-butennitrile
610   $ahalide perovskite
610   $azeolites
610   $aelectrospinning
610   $aRh
610   $aTi3C2Tx
610   $aheterostructures
610   $ahydroxytyrosol
610   $ametal?organic frameworks
610   $aphotocatalysis
610   $aNi/ZrO2
610   $athe maximum included sphere
610   $afunctionalized olefin
610   $aselective hydrogenation
610   $athiazoles
610   $aoxidation
610   $avisible-light
610   $ared P
610   $achitosan-MgO nanocomposite
610   $aZnO
610   $ag-C3N4/TiO2
610   $ahydroformylation
610   $asteric constraint
700   $aChu$b Wei(Willy)$4auth$01323728
702   $aYentekakis$b Ioannis$4auth
906   $aBOOK
912   $a9910404083103321
996   $aAdvances in Heterocatalysis by Nanomaterials$93035782
997   $aUNINA