Quantum Effects in Chemical Reactions under Polaritonic Vibrational Strong Coupling

Quantum Effects in Chemical Reactions under Polaritonic Vibrational Strong Coupling

The electromagnetic field in an optical cavity can dramatically modify and even control chemical reactivity via vibrational strong coupling (VSC). Since the typical vibration and cavity frequencies are considerably larger than thermal energy, it is essential to adopt a quantum description of cavity-...

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Bibliographic Details
Published in:The journal of physical chemistry letters Vol. 12; no. 39; pp. 9531 - 9538
Main Authors: Yang, Pei-Yun, Cao, Jianshu
Format: Journal Article
Language:English
Published: American Chemical Society 07-10-2021
Subjects:
Physical Insights into Quantum Phenomena and Function
Online Access:Get full text
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Summary:The electromagnetic field in an optical cavity can dramatically modify and even control chemical reactivity via vibrational strong coupling (VSC). Since the typical vibration and cavity frequencies are considerably larger than thermal energy, it is essential to adopt a quantum description of cavity-catalyzed adiabatic chemical reactions. Using quantum transition state theory (TST), we examine the coherent nature of adiabatic reactions in cavities and derive the cavity-induced changes in eigenfrequencies, zero-point energy, and quantum tunneling. The resulting quantum TST calculation allows us to explain and predict the resonance effect (i.e., maximal kinetic modification via tuning the cavity frequency), collective effect (i.e., linear scaling with the molecular density), and selectivity (i.e., cavity-induced control of the branching ratio). The TST calculation is further supported by perturbative analysis of polariton normal modes, which not only provides physical insights to cavity-catalyzed chemical reactions but also presents a general approach to treat other VSC phenomena.
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ISSN:1948-7185
1948-7185
DOI:10.1021/acs.jpclett.1c02210