Nanostructuring confinement for controllable interfacial charge transfer
Carbon nanostructures supported semiconductors are common in photocatalytic and photoelectrochemical applications, as it is expected that the nanoconductors can improve the spatial separation and transport of photogenerated charge carriers. Transfer of charge carriers through the carbon-semiconducto...
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sg-ntu-dr.10356-1508352021-07-30T10:49:55Z Nanostructuring confinement for controllable interfacial charge transfer Qiao, Wei Tao, Hua Bing Liu, Bin Chen, Jiazang School of Chemical and Biomedical Engineering Engineering::Chemical engineering Change Transfer Charge Transport Carbon nanostructures supported semiconductors are common in photocatalytic and photoelectrochemical applications, as it is expected that the nanoconductors can improve the spatial separation and transport of photogenerated charge carriers. Transfer of charge carriers through the carbon-semiconductor interface is the key electronic process, which determines the role of charge separation channels, and is sensitively influenced by band structures of the semiconductor near the contacts. Usually, this electronic process suffers from excessive energy dissipation by thermionic emission, which will undesirably prevent the interfacial charge transfer and eventually aggravate the recombination of photogenerated charge carriers. Unfortunately, this critical issue has hardly been consciously considered. Here, ultrathin dopant-free tunneling interlayers coated on the surface of graphene and sandwiched between the carbon sheets and the semiconductor nanostructures are adopted as a model system to demonstrate energy saving for the interfacial charge transfer. The nanostructuring confinement of band bending within the ultrathin interlayers in contact with the graphene sheets effectively narrows the width of the potential barriers, which enables tunneling of a substantial number of photogenerated electrons to the co-catalysts without unduly consuming energy. Besides, the dopant-free tunneling interlayers simultaneously block the transferred electrons in the sandwiched graphene sheets from leakage. The authors acknowledge National Natural Science Foundation of China (Nos.: 21773285 and 91545116), State Key Laboratory of Coal Conversion (Nos.: 2018BWZ004 and J17-18-913-1), CAS Pioneer “Hundred Talents Program”, Start-Up Grant of Institute of Coal Chemistry and Taishan scholar advantage and characteristic discipline team of Eco chemical process and technology for financial support. 2021-07-30T10:49:55Z 2021-07-30T10:49:55Z 2019 Journal Article Qiao, W., Tao, H. B., Liu, B. & Chen, J. (2019). Nanostructuring confinement for controllable interfacial charge transfer. Small, 15(29), 1804391-. https://dx.doi.org/10.1002/smll.201804391 1613-6810 0000-0002-4685-2052 https://hdl.handle.net/10356/150835 10.1002/smll.201804391 30663213 2-s2.0-85060328071 29 15 1804391 en Small © 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. All rights reserved. |
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Engineering::Chemical engineering Change Transfer Charge Transport Qiao, Wei Tao, Hua Bing Liu, Bin Chen, Jiazang Nanostructuring confinement for controllable interfacial charge transfer |
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Carbon nanostructures supported semiconductors are common in photocatalytic and photoelectrochemical applications, as it is expected that the nanoconductors can improve the spatial separation and transport of photogenerated charge carriers. Transfer of charge carriers through the carbon-semiconductor interface is the key electronic process, which determines the role of charge separation channels, and is sensitively influenced by band structures of the semiconductor near the contacts. Usually, this electronic process suffers from excessive energy dissipation by thermionic emission, which will undesirably prevent the interfacial charge transfer and eventually aggravate the recombination of photogenerated charge carriers. Unfortunately, this critical issue has hardly been consciously considered. Here, ultrathin dopant-free tunneling interlayers coated on the surface of graphene and sandwiched between the carbon sheets and the semiconductor nanostructures are adopted as a model system to demonstrate energy saving for the interfacial charge transfer. The nanostructuring confinement of band bending within the ultrathin interlayers in contact with the graphene sheets effectively narrows the width of the potential barriers, which enables tunneling of a substantial number of photogenerated electrons to the co-catalysts without unduly consuming energy. Besides, the dopant-free tunneling interlayers simultaneously block the transferred electrons in the sandwiched graphene sheets from leakage. |
| author2 |
School of Chemical and Biomedical Engineering |
| author_facet |
School of Chemical and Biomedical Engineering Qiao, Wei Tao, Hua Bing Liu, Bin Chen, Jiazang |
| format |
Article |
| author |
Qiao, Wei Tao, Hua Bing Liu, Bin Chen, Jiazang |
| author_sort |
Qiao, Wei |
| title |
Nanostructuring confinement for controllable interfacial charge transfer |
| title_short |
Nanostructuring confinement for controllable interfacial charge transfer |
| title_full |
Nanostructuring confinement for controllable interfacial charge transfer |
| title_fullStr |
Nanostructuring confinement for controllable interfacial charge transfer |
| title_full_unstemmed |
Nanostructuring confinement for controllable interfacial charge transfer |
| title_sort |
nanostructuring confinement for controllable interfacial charge transfer |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/150835 |
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1707050441602236416 |