Photothermal Effect, Local Field Dependence, and Charge Carrier Relaying Species in Plasmon-Driven Photocatalysis: A Case Study of Aerobic Nitrothiophenol Coupling Reaction

Zhang, Qingfeng; Zhou, Yadong; Fu, Xiaoqi; Villarreal, Esteban; Sun, Lichao; Zou, Shengli; Wang, Hui

doi:10.1021/acs.jpcc.9b08181

Cited by 35 publications

(48 citation statements)

References 58 publications

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“…In the case of a photochemical process in plasmonics, such as near-field enhancement of photochemical reactions or hot-charge-carrier-assisted redox reactions at the nanoparticle surface, the rate η 92 , 2016 93 , 2017 26,94 , 2018 23,24,41,42,56,84,95 , 2019 22,23,27,38,[48][49][50][96][97][98][99] , 2020 [100][101][102][103] photons and therefore to the incident light power impinging on the sample. This assumption holds true for CW illumination under moderate light power and may deviate toward a super-linear dependence for very high power 31 or under fs-pulsed laser illumination due to multiphoton absorption [32][33][34][35] .…”

Section: Procedures # 1: Varying the Illumination Powermentioning

confidence: 99%

Simple experimental procedures to distinguish photothermal from hot-carrier processes in plasmonics

et al. 2020

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Light absorption and scattering of plasmonic metal nanoparticles can lead to non-equilibrium charge carriers, intense electromagnetic near-fields, and heat generation, with promising applications in a vast range of fields, from chemical and physical sensing to nanomedicine and photocatalysis for the sustainable production of fuels and chemicals. Disentangling the relative contribution of thermal and non-thermal contributions in plasmon-driven processes is, however, difficult. Nanoscale temperature measurements are technically challenging, and macroscale experiments are often characterized by collective heating effects, which tend to make the actual temperature increase unpredictable. This work is intended to help the reader experimentally detect and quantify photothermal effects in plasmon-driven chemical reactions, to discriminate their contribution from that due to photochemical processes and to cast a critical eye on the current literature. To this aim, we review, and in some cases propose, seven simple experimental procedures that do not require the use of complex or expensive thermal microscopy techniques. These proposed procedures are adaptable to a wide range of experiments and fields of research where photothermal effects need to be assessed, such as plasmonic-assisted chemistry, heterogeneous catalysis, photovoltaics, biosensing, and enhanced molecular spectroscopy.

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Section: Procedures # 1: Varying the Illumination Powermentioning

confidence: 99%

Simple experimental procedures to distinguish photothermal from hot-carrier processes in plasmonics

et al. 2020

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“…Consequently, many publications use quasi-single molecular kinetics to extract a reaction rate of dimerization. [20,23,25,36] However, to be the limiting step, the activation by energetic electrons must be the slowest process in the reaction. This is rather unlikely, as the thermalization time of energetic electrons, which is the timescale in which the activation must occur, is in the order of a few fs.…”

Section: Resultsmentioning

confidence: 99%

“…[12] Examples range from the dissociation of H2, [11,13] via the reduction H2O [14] and of CO2, [15] to complex organic N-N or C-C coupling reactions. [16][17][18][19][20][21][22][23][24][25] The latter reaction type is particularly interesting as it forms the basis for true photosynthetic capabilities.…”

Section: Introductionmentioning

confidence: 99%

“…In order to advance the discussion on the role of photoheating in plasmon-driven chemistry, we investigated the light-intensity dependence of the reaction rate of a deliberately complex multistep reaction: the photodimerization of 4-nitrothiophenol (4NTP) to 4-,4'mercaptoazobenzne (DMAB) in the presence of gold nanoparticles. As this reaction has become somewhat the model instance for plasmon induced coupling reactions, [17][18][19][20][21][22]24,25,30] it is of no surprise that several studies have already approached the influence photoheating in the past.…”

Section: Introductionmentioning

confidence: 99%

“…[17,[20][21][22] On the one hand, Golubev et al demonstrated that under reaction conditions that do not cause a reduction of 4NTP upon illumination, the reduction could be started by additionally increasing the temperature. [21] Moreover, Zhang et al presented a superlinear increase of the reaction rate on temperature, [20] which can be interpreted as sign of a photothermal effect. On the other hand, seemingly opposing results were published by Keller and Frontiera, who measured the photoheating by ultrafast Raman thermometry.…”

Section: Introductionmentioning

confidence: 99%

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Decoding the kinetic limitations of plasmon catalysis: the case of 4-nitrothiophenol dimerization

et al. 2020

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Photothermal Chemistry Based on Solar Energy: From Synergistic Effects to Practical Applications

Hong

Deng

et al. 2021

Advanced Science

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With the development of society, energy shortage and environmental problems have become more and more outstanding. Solar energy is a clean and sustainable energy resource, potentially driving energy conversion and environmental remediation reactions. Thus, solar‐driven chemistry is an attractive way to solve the two problems. Photothermal chemistry (PTC) is developed to achieve full‐spectral utilization of the solar radiation and drive chemical reactions more efficiently under relatively mild conditions. In this review, the mechanisms of PTC are summarized from the aspects of thermal and non‐thermal effects, and then the interaction and synergy between these two effects are sorted out. In this paper, distinguishing and quantifying these two effects is discussed to understand PTC processes better and to design PTC catalysts more methodically. However, PTC is still a little far away from practical. Herein, several key points, which must be considered when pushing ahead with the engineering application of PTC, are proposed, along with some workable suggestions on the practical application. This review provides a unique perspective on PTC, focusing on the synergistic effects and pointing out a possible direction for practical application.

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Photothermal Effect, Local Field Dependence, and Charge Carrier Relaying Species in Plasmon-Driven Photocatalysis: A Case Study of Aerobic Nitrothiophenol Coupling Reaction

Cited by 35 publications

References 58 publications

Simple experimental procedures to distinguish photothermal from hot-carrier processes in plasmonics

Simple experimental procedures to distinguish photothermal from hot-carrier processes in plasmonics

Decoding the kinetic limitations of plasmon catalysis: the case of 4-nitrothiophenol dimerization

Photothermal Chemistry Based on Solar Energy: From Synergistic Effects to Practical Applications

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