Two-dimensional metal-dielectric hybrid-structured film with titanium oxide for enhanced visible light absorption and photo-catalytic application
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- 作者:Joonmo ParkaAuthor Vitae ; Hee Jun KimaAuthor Vitae ; SangHyeon NambAuthor Vitae ; Hyowook KimbAuthor Vitae ; Hak-Jong ChoicAuthor Vitae ; Youn Jeong JangeAuthor Vitae ; Jae Sung LeedAuthor Vitae ; Jonghwa ShinbAuthor Vitae ; Heon Leec ; heon.lee@gmail.com" class="auth_mail" title="E-mail the corresponding authorAuthor Vitae ; Jeong Min Baika ; jbaik@unist.ac.kr" class="auth_mail" title="E-mail the corresponding authorAuthor Vitae
- 关键词:2-dimensional Design ; TiO2 ; Visible Light Absorption ; Photocatalyst ; Water-splitting
- 刊名:Nano Energy
- 出版年:2016
- 出版时间:March 2016
- 年:2016
- 卷:21
- 期:Complete
- 页码:115-122
- 全文大小:3815 K
文摘
Two-dimensional design based on ultrathin TiO2 film for enhanced visible light absorption and photo-catalytic applications is reported, which mainly consists of three layers of gold film, TiO2 film, and gold nanoparticles (Au NPs). The Au and TiO2 films are produced by e-beam evaporation and atomic layer deposition, respectively, in a carefully controlled way to minimize surface roughness. As compared with bare TiO2 film, the Au NPs/TiO2/Au film significantly increased the photoactivity over the entire UV and visible wavelength range. The Au film increases the light absorption in the UV region with TiO2 acting as an impedance-matching layer, while the Au NPs increase the light absorption in the visible region due to the plasmonic resonance effects, increasing the photocurrent under visible light. 3D numerical simulation results suggest that the Au film also plays an important role in enhancing the electrical field intensity at the TiO2 film in contact with Au NPs, by efficient excitation of localized surface plasmon resonances, thereby, contributing to the enhanced photoactivity of the film in the visible range. This simple system may serve as an efficient platform for solar energy conversion utilizing the whole UV-visible range of solar spectrum based on two-dimensional plasmonic photoelectrodes.