Hot electron-driven photocatalytic water splitting

Hou, Bingya; Shen, Lang; Shi, Haotian; Kapadia, Rehan; Cronin, Stephen B.

doi:10.1039/c6cp07542h

Cited by 42 publications

(39 citation statements)

References 22 publications

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“…Hot electrons, which are generated from the nonradiative relaxation of localized surface plasmons, are more energetic than those generated by direct photoexcitation [11][12][13][14][15]. The maximum utilization of hot electrons is significantly important to improve the photocatalytic performance of metal-semiconductor hybrids [16][17][18][19][20][21][22]. Several strategies have been proposed to optimize the hot electron injection in plasmonic composites, such as enhancing the near field of plasmonic metal nanocrystals [23][24][25], selectively placing a semiconductor on the position, where a strong near field is located [26,27].…”

Section: Introductionmentioning

confidence: 99%

Enhanced Photocatalytic Hydrogen Generation by Optimized Plasmonic Hot Electron Injection in Structure-Adjustable Au-ZnO Hybrids

Chen

Ding

2020

Catalysts

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Plasmonic Au-ZnO hybrids with adjustable structures (including Au-decorated ZnO and core–shell Au@ZnO with dense and porous ZnO shells) and the optimized hot electron-driven photocatalytic activity were successfully prepared. It was found that the Au@ZnO core–shell hybrids with porous morphology had the highest plasmon-enhanced photocatalytic hydrogen generation activity under visible light irradiation. The wavelength-dependent photocatalytic tests verified that Au@ZnO with porous ZnO shells had the highest apparent quantum efficiency upon resonance excitation. The ultrafast transient absorption measurements revealed that Au@ZnO with porous ZnO shells had the fastest plasmon-induced hot electron injection, which was thought to be the reason for the improved photocatalytic activity. This work might provide a promising route to designing photocatalytic and photoelectric materials.

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Section: Introductionmentioning

confidence: 99%

Enhanced Photocatalytic Hydrogen Generation by Optimized Plasmonic Hot Electron Injection in Structure-Adjustable Au-ZnO Hybrids

Chen

Ding

2020

Catalysts

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“…[1][2][3] Specifically,t he plasmon-mediated carrier transfer (PMCT) across interfacial Schottky barriers at metal-semiconductor heterojunctions has been employed to promote various photocatalytic reactions. [1][2][3] Specifically,t he plasmon-mediated carrier transfer (PMCT) across interfacial Schottky barriers at metal-semiconductor heterojunctions has been employed to promote various photocatalytic reactions.…”

mentioning

confidence: 99%

“…Plasmonic metal nanostructures combining tunable optical properties with catalytically active surfaces offer intriguing opportunities for solar photocatalysis. [1][2][3] Specifically,t he plasmon-mediated carrier transfer (PMCT) across interfacial Schottky barriers at metal-semiconductor heterojunctions has been employed to promote various photocatalytic reactions. [1,4,5] So far, Au has been commonly used in most PMCT studies due to its plasmonic absorption of visible light and its capability to form Schottky barriers with semiconductors such as TiO 2 and ZnO.…”

mentioning

confidence: 99%

“…[1][2][3] Specifically,t he plasmon-mediated carrier transfer (PMCT) across interfacial Schottky barriers at metal-semiconductor heterojunctions has been employed to promote various photocatalytic reactions. [1,4,5] So far, Au has been commonly used in most PMCT studies due to its plasmonic absorption of visible light and its capability to form Schottky barriers with semiconductors such as TiO 2 and ZnO. [6][7][8] Recently,s everal studies have used inexpensive metals such as Al to substitute Au.…”

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confidence: 99%

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Plasmonic Nickel–TiO₂ Heterostructures for Visible‐Light‐Driven Photochemical Reactions

Huang

Goodsell

et al. 2019

Angewandte Chemie

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Plasmon-mediated carrier transfer (PMCT) at metal-semiconductor heterojunctions has been extensively exploited to drive photochemical reactions,offering intriguing opportunities for solar photocatalysis.H owever,t od ate,m ost studies have been conducted using noble metals.I nexpensive materials capable of generating and transferring hot carriers for photocatalysis via PMCT have been rarely explored. Here, we demonstrate that the plasmon excitation of nickel induces the transfer of both hot electrons and holes from Ni to TiO 2 in arationally designed Ni-TiO 2 heterostructure.Furthermore,it is discovered that the transferred hot electrons either occupy oxygen vacancies (V O )o rp roduce Ti 3+ on TiO 2 ,w hile the transferred hot holes are located on surface oxygens at TiO 2 . Moreover,t he transferred hot electrons are identified to play ap rimary role in driving the degradation of methylene blue (MB). Taken together,o ur results validate Ni as ap romising low-cost plasmonic material for prompting visible-light photochemical reactions.

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“…In our previous work, similar structures consisting of Au films with and without TiO 2 coatings were investigated. 30 For the bare metal electrodes, the mechanism of photocatalysis was attributed to hot electrons photoexcited in the metal. The mechanism of photocurrent generation in TiO 2 -coated Au electrodes was attributed to hot electron injected by the metal film because of our inability to detect these defect states in the UV-vis absorption process.…”

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confidence: 99%

Resonant and Selective Excitation of Photocatalytically Active Defect Sites in TiO₂

Hou

Shen

Shi

et al. 2019

ACS Appl. Mater. Interfaces

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It has been known for several decades that defects are largely responsible for the catalytically active sites on metal and semiconductor surfaces. However, it is difficult to directly probe these active sites because the defects associated with them are often relatively rare with respect to the stoichiometric crystalline surface. In the work presented here, we demonstrate a method to selectively probe defect-mediated photocatalysis, through differential AC photocurrent (PC) measurements. In this approach, electrons are photoexcited from the valence band to a relatively narrow distribution of sub-bandgap states in the TiO 2 , and then subsequently to the ions in solution. Because of their limited number, these defect states fill up quickly resulting in Pauli blocking, and are thereby undetectable under DC or CW excitation. In the method demonstrated here, the incident light is modulated with an optical chopper while the photocurrent is measured with a lock-in amplifier. Thin (5nm) films of TiO 2 deposited by atomic layer deposition (ALD) on various metal films, including Au, Cu, and Al, exhibit the same wavelength-dependent photocurrent spectra, with a broad peak centered around 2.0eV corresponding to the band-to-defect transition associated with the hydrogen evolution reaction (HER). While the UV-vis absorption spectra of these films show no features at 2.0eV, photoluminescence (PL) spectra of these photoelectrodes show a similar wavelength dependence with a peak around 2.0eV, corresponding to the sub-band gap emission associated with these defect sites. As a control, alumina (Al 2 O 3) films exhibit no PL or PC over the visible wavelength range. The AC photocurrent plotted as a function of electrode potential, shows a peak around-0.4 to-0.1V vs. NHE, as the monoenergetic defect states are tuned through a resonance with the HER potential. This approach enables the direct photo-excitation of catalytically active defect sites to be studied selectively without the interference of the continuum interband transitions or 3 the effects of Pauli blocking, which is limited by the slow turnover time of the catalytically active sites, typically on the order of 1 µsec. We believe this general approach provides an important new way to study the role of defects in catalysis in an area where selective spectroscopic studies of these are few.

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Hot electron-driven photocatalytic water splitting

Cited by 42 publications

References 22 publications

Enhanced Photocatalytic Hydrogen Generation by Optimized Plasmonic Hot Electron Injection in Structure-Adjustable Au-ZnO Hybrids

Enhanced Photocatalytic Hydrogen Generation by Optimized Plasmonic Hot Electron Injection in Structure-Adjustable Au-ZnO Hybrids

Plasmonic Nickel–TiO₂ Heterostructures for Visible‐Light‐Driven Photochemical Reactions

Resonant and Selective Excitation of Photocatalytically Active Defect Sites in TiO₂

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Hot electron-driven photocatalytic water splitting

Cited by 42 publications

References 22 publications

Enhanced Photocatalytic Hydrogen Generation by Optimized Plasmonic Hot Electron Injection in Structure-Adjustable Au-ZnO Hybrids

Enhanced Photocatalytic Hydrogen Generation by Optimized Plasmonic Hot Electron Injection in Structure-Adjustable Au-ZnO Hybrids

Plasmonic Nickel–TiO2 Heterostructures for Visible‐Light‐Driven Photochemical Reactions

Resonant and Selective Excitation of Photocatalytically Active Defect Sites in TiO2

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Plasmonic Nickel–TiO₂ Heterostructures for Visible‐Light‐Driven Photochemical Reactions

Resonant and Selective Excitation of Photocatalytically Active Defect Sites in TiO₂