LEADER 04998nam 2201117z- 450 001 9910640000303321 005 20231214133539.0 010 $a3-0365-5912-4 035 $a(CKB)5470000001633349 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/95859 035 $a(EXLCZ)995470000001633349 100 $a20202301d2022 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aNew Trends in Catalysis for Sustainable CO2 Conversion 210 $aBasel$cMDPI - Multidisciplinary Digital Publishing Institute$d2022 215 $a1 electronic resource (294 p.) 311 $a3-0365-5911-6 330 $aThis Special Issue on ?New Trends in Catalysis for Sustainable CO2 Conversion?, released in the Catalysts open access journal, shows new research about the development of catalysts and catalytic routes for CO2 valorization, in addition to the optimization of the reaction conditions for the process. This issue includes ten articles and three reviews about different innovative processes for CO2 conversion.Carbon capture and storage (CCS) is a physical process consisting of the separation the CO2 (emitted by industry and the combustion processes for energy generation) and its transportation to geological storage isolates it from the atmosphere in the long term. However, the most promising routes for CO2 mitigation are those pursuing its catalytic valorization. By applying specific catalysts and suitable operating conditions, CO2 molecules react with other components to form longer chains (i.e., hydrocarbons). Accordingly, effort should be made to catalytically valorize CO2 (alone or co-fed with syngas) as an alternative way of reducing greenhouse gas emissions and obtaining high-value fuels and chemicals. Carbon capture and utilization (CCU) is a developing field with significant demand for research in the following aspects:The development of new catalysts, catalytic routes, and technologies for CO2 conversion;The study of new processes for obtaining fuels and chemicals from CO2;Optimization of the catalysts and the reaction conditions for these processes;Further steps in advanced processes using CO2-rich feeds (H2+CO2 or CO2 mixed with syngas), increasing product yields. 606 $aTechnology: general issues$2bicssc 606 $aHistory of engineering & technology$2bicssc 606 $aEnvironmental science, engineering & technology$2bicssc 610 $acarbon dioxide 610 $ahydrogenation 610 $acatalyst 610 $agas hourly space velocity (GHSV) 610 $afixed-bed reactor 610 $aCO2-H2O photo-co-processing 610 $aVIS-light driven reactions 610 $aCO2 reduction 610 $aphotocatalysts properties 610 $asoft oxidant 610 $aoxidation 610 $adehydrogenation 610 $anano-catalyst 610 $aelectrochemical reduction of CO2 610 $aionic liquids 610 $apropylene carbonate 610 $aimidazolium cation 610 $agreenhouse gas 610 $aclimate change 610 $aCO2 decomposition 610 $aCO2 utilization 610 $aSrFeO3?x 610 $aCO2 methanation 610 $aNi-xSi/ZrO2 610 $aSi promotion 610 $aoxygen vacancies 610 $aCO2 hydrogenation 610 $alight olefins 610 $acatalyst deactivation 610 $aCO2-Fischer-Tropsch (CO2-FT) 610 $airon-based catalysts 610 $amethanol to olefins 610 $abifunctional composite catalysts 610 $aSAPO-34 610 $aphotocatalysis 610 $acarbon-TiO2 610 $ananocarbon 610 $acarbon allotropes 610 $acarbon nanotubes 610 $acarbon nanofibers 610 $acarbon nano-onions 610 $acarbon dioxide electrolysis 610 $amolten carbonate 610 $agreenhouse gas mitigation 610 $acycloaddition 610 $aionic liquid 610 $adeep eutectic solvents 610 $aonium salt 610 $ahomogeneous catalysts 610 $aheterogeneous catalysis 610 $aCO2 conversion 610 $amethane 610 $ahydrocarbons 610 $airon oxide 610 $acopper nanoparticles 610 $abiomass 610 $aFischer-Tropsch synthesis 610 $acarbon-supported iron catalyst 610 $agasoline 610 $adiesel 615 7$aTechnology: general issues 615 7$aHistory of engineering & technology 615 7$aEnvironmental science, engineering & technology 700 $aEren?a Loizaga$b Javier$4edt$00 702 $aAteka$b Ainara$4edt 702 $aEren?a Loizaga$b Javier$4oth 702 $aAteka$b Ainara$4oth 906 $aBOOK 912 $a9910640000303321 996 $aNew Trends in Catalysis for Sustainable CO2 Conversion$93029037 997 $aUNINA