Journal
NATURE COMMUNICATIONS
Volume 13, Issue 1, Pages -Publisher
NATURE PORTFOLIO
DOI: 10.1038/s41467-022-28409-2
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Funding
- Independent Research Fund Denmark-Sapere Aude starting grant [7026-00037A]
- Swedish Research Council VR [201705337]
- Crafood foundation [20200522]
- Swedish Energy Agency research grant
- NanoLund seed project [136470]
- Swedish Research Council (VR) [2018-05393]
- P220 program of Government of Russia [075-15-2021-604]
- Research Fund for International Young Scientists from NSFC, China [21950410515]
- Chinese Scholarship Council
- Vinnova [2018-05393] Funding Source: Vinnova
- Swedish Research Council [2018-05393] Funding Source: Swedish Research Council
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In this study, the researchers investigated the excitation energy-dependent pathways of internal photo-induced charge transfer in rhenium(I)-carbonyl-diimine complexes/covalent organic frameworks hybrid catalysts. The findings revealed that under high-energy photon excitation, the electron transfer pathway resulted in longer-lived excited states, facilitating the conversion of carbon dioxide to carbon monoxide.
Rhenium(I)-carbonyl-diimine complexes have emerged as promising photocatalysts for carbon dioxide reduction with covalent organic frameworks recognized as perfect sensitizers and scaffold support. Such Re complexes/covalent organic frameworks hybrid catalysts have demonstrated high carbon dioxide reduction activities but with strong excitation energy-dependence. In this paper, we rationalize this behavior by the excitation energy-dependent pathways of internal photo-induced charge transfer studied via transient optical spectroscopies and time-dependent density-functional theory calculation. Under band-edge excitation, the excited electrons are quickly injected from covalent organic frameworks moiety into catalytic Rhenium(I) center within picosecond but followed by fast backward geminate recombination. While under excitation with high-energy photon, the injected electrons are located at high-energy levels in Rhenium(I) centers with longer lifetime. Besides those injected electrons to Rhenium(I) center, there still remain some long-lived electrons in covalent organic frameworks moiety which is transferred back from Rhenium(I). This facilitates the two-electron reaction of carbon dioxide conversion to carbon monoxide. Re complexes within covalent organic frameworks have emerged as promising photocatalysts for CO2 reduction. Here, authors identify a high-energy electron transfer pathway during CO2 reduction that results in longer-lived excited states than a low-energy electron transfer pathway.
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