Use of QM/MM Surface Hopping Simulations to Understand Thermally Activated Rare-Event Nonadiabatic Transitions in the Condensed Phase

Coffman, Alec J.; Jin, Zuxin; Chen, Junhan; Subotnik, Joseph E.; Cofer-Shabica, D. Vale

doi:10.1021/acs.jctc.3c00276

J. Chem. Theory Comput.

2023

DOI: 10.1021/acs.jctc.3c00276

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Use of QM/MM Surface Hopping Simulations to Understand Thermally Activated Rare-Event Nonadiabatic Transitions in the Condensed Phase

Alec J. Coffman,

Zuxin Jin,

Junhan Chen

et al.

Abstract: We implement a rare-event sampling scheme for quantifying the rate of thermally activated nonadiabatic transitions in the condensed phase. Our Quantum mechanics/molecular mechanics (QM/MM) methodology uses the recently developed Interface for NonAdiabatic QM/MM in Solvent (INAQS) package to interface an elementary electronic structure package and a popular open-source molecular dynamics software (GROMACS) to simulate an electron transfer event between two stationary ions in a solution of acetonitrile solvent m… Show more

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2024

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Coherent control from quantum commitment probabilities

Anderson,

Dodin,

Fay

et al. 2024

The Journal of Chemical Physics

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We introduce a general definition of a quantum committor in order to clarify reaction mechanisms and facilitate control in processes where coherent effects are important. With a quantum committor, we generalize the notion of a transition state to quantum superpositions and quantify the effect of interference on the progress of the reaction. The formalism is applicable to any linear quantum master equation supporting metastability for which absorbing boundary conditions designating the reactant and product states can be applied. We use this formalism to determine the dependence of the quantum transition state on coherences in a polaritonic system and optimize the initialization state of a conical intersection model to control reactive outcomes, achieving yields of the desired state approaching 100%. In addition to providing a practical tool, the quantum committor provides a conceptual framework for understanding reactions in cases when classical intuitions fail.

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Coherent control from quantum commitment probabilities

Anderson,

Dodin,

Fay

et al. 2024

The Journal of Chemical Physics

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show abstract

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Use of QM/MM Surface Hopping Simulations to Understand Thermally Activated Rare-Event Nonadiabatic Transitions in the Condensed Phase

Cited by 1 publication

References 85 publications

Coherent control from quantum commitment probabilities

Coherent control from quantum commitment probabilities

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