FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4200537481> ?p ?o ?g. }

• W4200537481 endingPage "4544" @default.
• W4200537481 startingPage "4530" @default.
• W4200537481 abstract "ConspectusDuring the last few decades, the design of catalytic systems for CO2 reduction has been extensively researched and generally involves (1) traditional approaches using molecular organic/organometallic materials and heterogeneous inorganic semiconductors and (2) combinatory approaches wherein these materials are combined as needed. Recently, we have devised a number of new TiO2-mediated multicomponent hybrid systems that synergistically integrate the intrinsic merits of various materials, namely, molecular photosensitizers/catalysts and n-type TiO2 semiconductors, and lower the energetic and kinetic barriers between components. We have termed such multicomponent hybrid systems assembled from the hybridization of various organic/inorganic/organometallic units in a single platform inorganometallic photocatalysts. The multicomponent inorganometallic (MIOM) hybrid system onto which the photosensitizer and catalyst are coadsorbed efficiently eliminates the need for bulk-phase diffusion of the components and avoids the accumulation of radical intermediates that invokes a degradation pathway, in contrast to the homogeneous system, in which the free reactive species are concentrated in a confined reaction space. In particular, in energetic terms, we discovered that in nonaqueous media, the conduction band (CB) levels of reduced TiO2 (TiO2(e-)) are positioned at a higher level (in the range -1.5 to -1.9 V vs SCE). This energetic benefit of reduced TiO2 allows smooth electron transfer (ET) from injected electrons (TiO2(e-)) to the coadsorbed CO2 reduction catalyst, which requires relatively high reducing power (at least more than -1.1 V vs SCE). On the other hand, the existence of various shallow surface trapping sites and surface bands, which are 0.3-1.0 eV below the CB of TiO2, efficiently facilitates electron injection from any photosensitizer (including dyes having low excited energy levels) to TiO2 without energetic limitation. This is contrasted with most photocatalytic systems, wherein successive absorption of single high-energy photons is required to produce excited states with enough energy to fulfill photocatalytic reaction, which may allow unwanted side reactions during photocatalysis. In this Account, we present our recent research efforts toward advancing these MIOM hybrid systems for photochemical CO2 reduction and discuss their working mechanisms in detail. Basic ET processes within the MIOM system, including intervalence ET in organic/organometallic redox systems, metal-to-ligand charge transfer of organometallic complexes, and interfacial/outer-sphere charge transfer between components, were investigated by conducting serial photophysical and electrochemical analyses. Because such ET events occur primarily at the interface between the components, the efficiency of interfacial ET between the molecular components (organic/organometallic photosensitizers and molecular reduction catalysts) and the bulk inorganic solid (mainly n-type TiO2 semiconductors) has a significant influence on the overall photochemical reaction kinetics and mechanism. In some TiO2-mediated MIOM hybrids, the chemical attachment of organic or organometallic photosensitizing units onto TiO2 semiconductors efficiently eliminates the step of diffusion/collision-controlled ET between components and prevents the accumulation of reactive species (oxidatively quenched cations or reductively quenched anions) in the reaction solution, ensuring steady photosensitization over an extended reaction period. The site isolation of a single-site organometallic catalyst employing TiO2 immobilization promotes the monomeric catalytic pathway during the CO2 reduction process, resulting in enhanced product selectivity and catalytic performance, including lifetime extension. In addition, as an alternative inorganic solid scaffold, the introduction of a host porphyrin matrix (interlinked in a metal-organic framework (MOF) material) led to efficient and durable photocatalytic CO2 conversion by the new MOF-Re(I) hybrid as a result of efficient light harvesting/exciton migration in the porphyrinic MOF and rapid quenching of the photogenerated electrons by the doped Re(I) catalytic sites. Overall, the case studies presented herein provide valuable insights for the rational design of advanced multicomponent hybrid systems for artificial photosynthesis involving CO2 reduction." @default.
• W4200537481 created "2021-12-31" @default.
• W4200537481 creator A5042002197 @default.
• W4200537481 creator A5067173819 @default.
• W4200537481 creator A5088524416 @default.
• W4200537481 date "2021-12-09" @default.
• W4200537481 modified "2023-10-15" @default.
• W4200537481 title "Inorganometallic Photocatalyst for CO₂ Reduction" @default.
• W4200537481 cites W1967320284 @default.
• W4200537481 cites W1971779604 @default.
• W4200537481 cites W1978145295 @default.
• W4200537481 cites W1983589290 @default.
• W4200537481 cites W1985959950 @default.
• W4200537481 cites W1986755516 @default.
• W4200537481 cites W1993157680 @default.
• W4200537481 cites W1993545510 @default.
• W4200537481 cites W2005794697 @default.
• W4200537481 cites W2008648807 @default.
• W4200537481 cites W2016901007 @default.
• W4200537481 cites W2018103942 @default.
• W4200537481 cites W2025806519 @default.
• W4200537481 cites W2028008988 @default.
• W4200537481 cites W2030917767 @default.
• W4200537481 cites W2033534524 @default.
• W4200537481 cites W2037963696 @default.
• W4200537481 cites W2039786475 @default.
• W4200537481 cites W2040310078 @default.
• W4200537481 cites W2056896873 @default.
• W4200537481 cites W2057833130 @default.
• W4200537481 cites W2068336593 @default.
• W4200537481 cites W2074292354 @default.
• W4200537481 cites W2078122806 @default.
• W4200537481 cites W2094703768 @default.
• W4200537481 cites W2095706733 @default.
• W4200537481 cites W2100181695 @default.
• W4200537481 cites W2116327492 @default.
• W4200537481 cites W2126688530 @default.
• W4200537481 cites W2130566039 @default.
• W4200537481 cites W2167264691 @default.
• W4200537481 cites W2176380301 @default.
• W4200537481 cites W2189487445 @default.
• W4200537481 cites W2302873685 @default.
• W4200537481 cites W2319195884 @default.
• W4200537481 cites W2320625878 @default.
• W4200537481 cites W2326451207 @default.
• W4200537481 cites W2326681786 @default.
• W4200537481 cites W2484494043 @default.
• W4200537481 cites W2520856544 @default.
• W4200537481 cites W2539992207 @default.
• W4200537481 cites W2564178799 @default.
• W4200537481 cites W2565880589 @default.
• W4200537481 cites W2577366206 @default.
• W4200537481 cites W2750044435 @default.
• W4200537481 cites W2756042010 @default.
• W4200537481 cites W2760798473 @default.
• W4200537481 cites W2774564380 @default.
• W4200537481 cites W2782984361 @default.
• W4200537481 cites W2795259398 @default.
• W4200537481 cites W2901959014 @default.
• W4200537481 cites W2912448260 @default.
• W4200537481 cites W2913853938 @default.
• W4200537481 cites W2968662096 @default.
• W4200537481 cites W2968844467 @default.
• W4200537481 cites W3007607881 @default.
• W4200537481 cites W3040162209 @default.
• W4200537481 cites W3046651813 @default.
• W4200537481 cites W3112888198 @default.
• W4200537481 cites W3118710615 @default.
• W4200537481 cites W3145214417 @default.
• W4200537481 cites W3175890295 @default.
• W4200537481 cites W3180295506 @default.
• W4200537481 cites W4242673452 @default.
• W4200537481 cites W600932620 @default.
• W4200537481 cites W656294911 @default.
• W4200537481 doi "https://doi.org/10.1021/acs.accounts.1c00579" @default.
• W4200537481 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/34881862" @default.
• W4200537481 hasPublicationYear "2021" @default.
• W4200537481 type Work @default.
• W4200537481 citedByCount "43" @default.
• W4200537481 countsByYear W42005374812022 @default.
• W4200537481 countsByYear W42005374812023 @default.
• W4200537481 crossrefType "journal-article" @default.
• W4200537481 hasAuthorship W4200537481A5042002197 @default.
• W4200537481 hasAuthorship W4200537481A5067173819 @default.
• W4200537481 hasAuthorship W4200537481A5088524416 @default.
• W4200537481 hasConcept C108225325 @default.
• W4200537481 hasConcept C121332964 @default.
• W4200537481 hasConcept C123669783 @default.
• W4200537481 hasConcept C159467904 @default.
• W4200537481 hasConcept C161790260 @default.
• W4200537481 hasConcept C171250308 @default.
• W4200537481 hasConcept C175583648 @default.
• W4200537481 hasConcept C178790620 @default.
• W4200537481 hasConcept C185592680 @default.
• W4200537481 hasConcept C192562407 @default.
• W4200537481 hasConcept C192937433 @default.
• W4200537481 hasConcept C21951064 @default.
• W4200537481 hasConcept C2779679103 @default.

• next