Optimal methodology for explicit solvation prediction of band edges of transition metal oxide photocatalysts

Authors
Park, Kyoung-WonKolpak, Alexie M.
Issue Date
2019-07-03
Publisher
NATURE PUBLISHING GROUP
Citation
COMMUNICATIONS CHEMISTRY, v.2
Abstract
The conduction and valence band edges (EC and EV) of a material relative to the water redox potential levels are critical factors governing photocatalytic water splitting activity. Here we discuss the large discrepancy in the experimentally measured EC and EV of various transition metal oxides (TMOs) in vacuum and in an aqueous solution. We speculate that the discrepancy stems from the different degree of electron transfer across the surface due to the different environment at the surface of the TMOs in vacuum and water. Accurately modeling the electronic structure at TMO/water interfaces is a significant challenge, however. Using first-principles density functional theory calculations on rutile titanium dioxide and cobalt monoxide model systems, here we identify the optimal approaches to accurately predict the band edge positions in vacuum and water. We then validate the optimized schemes on other TMOs, demonstrating good agreement with experimental measurements in both vacuum and water.
Keywords
RUTILE TIO2(110) SURFACE; 1ST-PRINCIPLES CALCULATIONS; ELECTRON-TRANSFER; WATER; SEMICONDUCTOR; ENERGETICS; INTERFACES; ALIGNMENT; COO; FLUORESCENCE; RUTILE TIO2(110) SURFACE; 1ST-PRINCIPLES CALCULATIONS; ELECTRON-TRANSFER; WATER; SEMICONDUCTOR; ENERGETICS; INTERFACES; ALIGNMENT; COO; FLUORESCENCE
ISSN
2399-3669
URI
https://pubs.kist.re.kr/handle/201004/119784
DOI
10.1038/s42004-019-0179-3
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KIST Article > 2019
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