Plasmon-Enhanced Catalysis: Distinguishing Thermal and Nonthermal Effects

Zhang, Xiao; Li, Xue–Qian; Reish, Matthew E.; Zhang, Du; Su, Neil Qiang; Gutiérrez, Yael; Moreno, Fernando; Yang, Weitao; Everitt, Henry O.; Liu, Jie

doi:10.1021/acs.nanolett.7b04776

Cited by 268 publications

(274 citation statements)

References 49 publications

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“…In papers I-III, the origin of the discrepancy between the measured temperature and the actual reactor temperature is simple to understand; its origin is in the fact that a thermometer was placed away from the reactor pellet, thus discarding any temperature gradients which appear in the reactor and beyond it (as was recently discussed in Refs. [13,33,34]).…”

Section: Discussionmentioning

confidence: 99%

“…However, as was demonstrated in Refs. [13,33,34] (and later acknowledged in IV), the temperatures can vary substantially inside the chemical reactor and they decay rapidly away from it; specifically, the temperature of the reactor can be very different (by 100s of degrees K) from the temperature measured by a thermocouple placed a few mm away. As shown below, indeed, the temperature measurements in I and II underestimated the reactor temperature, hence, led the authors to incorrect conclusions.…”

Section: Experimental Data Explained By Heatingmentioning

confidence: 99%

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Thermal effects – an alternative mechanism for plasmon-assisted photocatalysis

2020

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Recent experiments claimed that the enhancement of catalytic reaction rates occurs via the reduction of activation barriers driven by non-equilibrium ("hot") electrons in plasmonic metal nanoparticles. These experiments place plasmonic photo-catalysis as a promising path for enhancing the efficiency of various chemical reactions. Here, we argue that what appears to be photo-catalysis is in fact thermo-catalysis, driven by the well-known plasmon-enhanced ability of illuminated metallic nanoparticles to serve as heat sources. Specifically, we point to some of the most important papers in the field, and show that a simple theory of illumination-induced heating can explain the extracted experimental data to remarkable agreement, with minimal to no fit parameters. We further show that any small temperature difference between the photocatalysis experiment and a control experiment performed under uniform external heating is effectively amplified by the exponential sensitivity of the reaction, and very likely to be interpreted incorrectly as "hot" electron effects.

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Section: Discussionmentioning

confidence: 99%

Section: Experimental Data Explained By Heatingmentioning

confidence: 99%

Thermal effects – an alternative mechanism for plasmon-assisted photocatalysis

2020

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“…Therefore, it is apparent that both heat and light can play a role in these reactions, as also illustrated in ref. .…”

Section: Electromagnetic Hotspots and Hot Electronsmentioning

confidence: 99%

“Hot” in Plasmonics: Temperature‐Related Concepts and Applications of Metal Nanostructures

Kuppe

Rusimova

Ohnoutek

et al. 2019

Advanced Optical Materials

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Recent advances in nonlinear optics, hot electrons for renewable energy (e.g., solar cells and water‐splitting), acousto‐optics, nanometalworking, nanorobotics, steam generation, and photothermal cancer therapy are reviewed here. In all these areas, one of the key enabling properties is the ability of metallic nanoparticles to harvest and control light at the subwavelength scale by supporting coherent electronic oscillations, called localized surface plasmon resonances (LSPRs). Various physical properties and potential areas of application emerge depending on the decay mechanism of the LSPR and, especially, depending on the considered timescale. The field of plasmonics has mainly been associated with manipulating electromagnetic near‐fields at the nanoscale, where absorption is an obstacle. However, plasmonic absorption leads to a stream of temperature‐related phenomena that have only recently attracted significant attention. The goal of this review is to highlight exciting new areas of research (such as nanorobotics, nanometalworking, or acousto‐optical techniques) and to survey the most recent progress in more established areas (such as hot electrons, photothermal therapy, and plasmonic steam generation). To set each research area in context, the text is organized around the thermal cycle of the nanoparticles.

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“…Reaction rates depended on the different structures of Au‐1–4‐NCat , showing highest reactivity in the case of Au‐4‐NCat and similar to the Au‐multilayer NCat ( Au‐M‐NCat ), validating the influence of bilayer/multilayer‐confined plasmonic effect on reaction rates (Figure b and Figure S19). In the bilayer structure of nanocatalosomes, closely located plasmonic units with narrow interparticle gaps and cavities can form extensively coupled plasmonic hot‐spots which can concentrate high electromagnetic fields and other plasmon‐induced effects such as: instantaneous production/transfer of hot charge‐carriers and their equilibration with lattice through an electron‐phonon coupling resulting the photothermal increase in localized temperature; all these factors together are responsible for solar‐light induced high catalytic activities of nanocatalosomes. In order to investigate the individual role of photothermal effect, we tested the folding/unfolding of proteins in the presence of Au‐4‐NCat under light irradiation.…”

Section: Resultsmentioning

confidence: 99%

Nanocatalosomes as Plasmonic Bilayer Shells with Interlayer Catalytic Nanospaces for Solar‐Light‐Induced Reactions

et al. 2020

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Interest and challenges remain in designing and synthesizing catalysts with nature‐like complexity at few‐nm scale to harness unprecedented functionalities by using sustainable solar light. We introduce “nanocatalosomes”—a bio‐inspired bilayer‐vesicular design of nanoreactor with metallic bilayer shell‐in‐shell structure, having numerous controllable confined cavities within few‐nm interlayer space, customizable with different noble metals. The intershell‐confined plasmonically coupled hot‐nanospaces within the few‐nm cavities play a pivotal role in harnessing catalytic effects for various organic transformations, as demonstrated by “acceptorless dehydrogenation”, “Suzuki–Miyaura cross‐coupling” and “alkynyl annulation” affording clean conversions and turnover frequencies (TOFs) at least one order of magnitude higher than state‐of‐the‐art Au‐nanorod‐based plasmonic catalysts. This work paves the way towards next‐generation nanoreactors for chemical transformations with solar energy.

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Plasmon-Enhanced Catalysis: Distinguishing Thermal and Nonthermal Effects

Cited by 268 publications

References 49 publications

Thermal effects – an alternative mechanism for plasmon-assisted photocatalysis

Thermal effects – an alternative mechanism for plasmon-assisted photocatalysis

“Hot” in Plasmonics: Temperature‐Related Concepts and Applications of Metal Nanostructures

Nanocatalosomes as Plasmonic Bilayer Shells with Interlayer Catalytic Nanospaces for Solar‐Light‐Induced Reactions

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