Mechanistic Insights into Photocatalyzed H<sub>2</sub> Dissociation on Au Clusters

Wu, Qisheng; Zhou, Linsen; Schatz, George C.; Zhang, Yu; Guo, Hua

doi:10.1021/jacs.0c04491

Cited by 56 publications

(83 citation statements)

References 92 publications

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“…To resolve this failure of electronic friction theory, stochastic surface hopping methods such as IESH will likely be required. However, such methods need to be integrated with more realistic first-principles determined charge transfer states, 50 which remains very challenging for periodic metallic systems. To fully understand the case of NO on Au(111), additional experiments that provide insight into the trapping probability of highly vibrationally excited molecules at high incidence energies will be useful in the future.…”

Section: Discussionmentioning

confidence: 99%

Determining the Effect of Hot Electron Dissipation on Molecular Scattering Experiments at Metal Surfaces

Box

Zhang

Yin

et al. 2020

JACS Au

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Nonadiabatic effects that arise from the concerted motion of electrons and atoms at comparable energy and time scales are omnipresent in thermal and light-driven chemistry at metal surfaces. Excited (hot) electrons can measurably affect molecule–metal reactions by contributing to state-dependent reaction probabilities. Vibrational state-to-state scattering of NO on Au(111) has been one of the most studied examples in this regard, providing a testing ground for developing various nonadiabatic theories. This system is often cited as the prime example for the failure of electronic friction theory, a very efficient model accounting for dissipative forces on metal-adsorbed molecules due to the creation of hot electrons in the metal. However, the exact failings compared to experiment and their origin from theory are not established for any system because dynamic properties are affected by many compounding simulation errors of which the quality of nonadiabatic treatment is just one. We use a high-dimensional machine learning representation of electronic structure theory to minimize errors that arise from quantum chemistry. This allows us to perform a comprehensive quantitative analysis of the performance of nonadiabatic molecular dynamics in describing vibrational state-to-state scattering of NO on Au(111) and compare directly to adiabatic results. We find that electronic friction theory accurately predicts elastic and single-quantum energy loss but underestimates multiquantum energy loss and overestimates molecular trapping at high vibrational excitation. Our analysis reveals that multiquantum energy loss can potentially be remedied within friction theory whereas the overestimation of trapping constitutes a genuine breakdown of electronic friction theory. Addressing this overestimation for dynamic processes in catalysis and surface chemistry will likely require more sophisticated theories

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Section: Discussionmentioning

confidence: 99%

Determining the Effect of Hot Electron Dissipation on Molecular Scattering Experiments at Metal Surfaces

Box

Zhang

Yin

et al. 2020

JACS Au

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“…[ 46–48 ] Based on these well‐defined Au and Ag nanomaterials, the catalytic mechanisms are explored in depth from the views of energy transfer and molecular evolution. [ 49–54 ] Although Au and Ag nanomaterials exhibit remarkable catalytic performance in plasmonic catalysis, the high price of Au and Ag metals significantly hinders the practical applications in chemical industry and environmental protection. [ 55 ] Non‐noble metals, especially for Cu nanomaterials, offer attractive opportunities to replace noble metals in plasmonic catalysis, which also exhibit excellent LSPR effect from UV–vis to NIR.…”

Section: Introductionmentioning

confidence: 99%

Copper‐Based Plasmonic Catalysis: Recent Advances and Future Perspectives

et al. 2021

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With the capability of inducing intense electromagnetic field, energetic charge carriers, and photothermal effect, plasmonic metals provide a unique opportunity for efficient light utilization and chemical transformation. Earth‐abundant low‐cost Cu possesses intense and tunable localized surface plasmon resonance from ultraviolet‐visible to near infrared region. Moreover, Cu essentially exhibits remarkable catalytic performance toward various reactions owing to its intriguing physical and chemical properties. Coupling with light‐harvesting ability and catalytic function, plasmonic Cu serves as a promising platform for efficient light‐driven chemical reaction. Herein, recent advancements of Cu‐based plasmonic photocatalysis are systematically summarized, including designing and synthetic strategies for Cu‐based catalysts, plasmonic catalytic performance, and mechanistic understanding over Cu‐based plasmonic catalysts. What's more, approaches for the enhancement of light utilization efficiency and construction of active centers on Cu‐based plasmonic catalysts are highlighted and discussed in detail, such as morphology and size control, regulation of electronic structure, defect and strain engineering, etc. Remaining challenges and future perspectives for further development of Cu‐based plasmonic catalysis are also proposed.

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“…In the future, our goal will be to apply the present method to begin assessing non-adiabatic dynamics near plasmonic surfaces, which is nowadays a rather "hot" topic in physical chemistry [34].…”

Section: Discussionmentioning

confidence: 99%

Methods to Calculate Electronic Excited-state Dynamics For Molecules on Large Metal Clusters with Many States: Ensuring Fast Overlap Calculations and a Robust Choice of Phase

Chen

Cofer-Shabica

et al. 2021

Preprint

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We present an efficient set of methods for propagating excited-state dynamics involving a large number of electronic states based on a CIS electronic state overlap scheme. Specifically, (i) following Head-Gordon et al, we implement an exact evaluation of the overlap of singly-excited electronic states at different nuclear geometries using a biorthogonal basis, and (ii) we employ a unified protocol for choosing the correct phase for each adiabat at each geometry. For many-electron systems, the combination of these techniques significantly reduces the computational cost of integrating the electronic Schrodinger equation and imposes minimal overhead on top of the underlying electronic structure calculation. As a demonstration, we calculate the electronic excited-state dynamics for a hydrogen molecule scattering off a silver metal cluster, focusing on high-lying excited states where many electrons can be excited collectively and crossings are plentiful. Interestingly, we find that the high-lying, plasmon-like collective excitation spectrum changes with nuclear dynamics, highlighting the need to simulate non-adiabatic nuclear dynamics and plasmonic excitations simultaneously. In the future, the combination of methods presented here should help theorists build a mechanistic understanding of plasmon-assisted charge transfer and excitation energy relaxation processes near a nanoparticle or metal surface.

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Mechanistic Insights into Photocatalyzed H₂ Dissociation on Au Clusters

Cited by 56 publications

References 92 publications

Determining the Effect of Hot Electron Dissipation on Molecular Scattering Experiments at Metal Surfaces

Determining the Effect of Hot Electron Dissipation on Molecular Scattering Experiments at Metal Surfaces

Copper‐Based Plasmonic Catalysis: Recent Advances and Future Perspectives

Methods to Calculate Electronic Excited-state Dynamics For Molecules on Large Metal Clusters with Many States: Ensuring Fast Overlap Calculations and a Robust Choice of Phase

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Mechanistic Insights into Photocatalyzed H2 Dissociation on Au Clusters

Cited by 56 publications

References 92 publications

Determining the Effect of Hot Electron Dissipation on Molecular Scattering Experiments at Metal Surfaces

Determining the Effect of Hot Electron Dissipation on Molecular Scattering Experiments at Metal Surfaces

Copper‐Based Plasmonic Catalysis: Recent Advances and Future Perspectives

Methods to Calculate Electronic Excited-state Dynamics For Molecules on Large Metal Clusters with Many States: Ensuring Fast Overlap Calculations and a Robust Choice of Phase

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Mechanistic Insights into Photocatalyzed H₂ Dissociation on Au Clusters