The use of ring polymer molecular dynamics (RPMD) for the direct simulation of electron transfer (ET) reaction dynamics is analyzed in the context of Marcus theory, semiclassical instanton theory, and exact quantum dynamics approaches. For both fully atomistic and system-bath representations of condensed-phase ET, we demonstrate that RPMD accurately predicts both ET reaction rates and mechanisms throughout the normal and activationless regimes of the thermodynamic driving force. Analysis of the ensemble of reactive RPMD trajectories reveals the solvent reorganization mechanism for ET that is anticipated in the Marcus rate theory, and the accuracy of the RPMD rate calculation is understood in terms of its exact description of statistical flu...
Ring polymer molecular dynamics (RPMD) is used to directly simulate the injection and relaxation of ...
A partial linearized path integral approach is used to calculate the condensed phase electron transf...
The thermal rate constants of two prototypical insertion-type reactions, namely, N/O + H<sub>2</sub>...
The use of ring polymer molecular dynamics (RPMD) for the direct simulation of electron transfer (ET...
We demonstrate that the ring-polymer molecular dynamics (RPMD) method is equivalent to an automated ...
We extend ring-polymer molecular dynamics (RPMD) to allow for the direct simulation of general, elec...
We investigate the performance of the recently developed kinetically-constrained ring polymer molecu...
We take the golden-rule instanton method derived in the previous paper [J. O. Richardson, R. Bauer, ...
100 pagesThe transfer of electrons from one entity to another, the former – the electron donor and t...
Understanding the mechanisms and timescales of charge and energy transfer processes in large, comple...
The coupled transfer of electrons and protons is a central feature of biological and molecular catal...
The semiclassical instanton expression for the tunneling splitting between two symmetric wells is re...
We address the calculation of microcanonical reaction rates for processes involving significant nucl...
This thesis presents the ring polymer molecular dynamics (RPMD) approximation to the Kubo-transforme...
We apply Thermostatted Ring Polymer Molecular Dynamics (TRPMD), a recently-proposed approximate quan...
Ring polymer molecular dynamics (RPMD) is used to directly simulate the injection and relaxation of ...
A partial linearized path integral approach is used to calculate the condensed phase electron transf...
The thermal rate constants of two prototypical insertion-type reactions, namely, N/O + H<sub>2</sub>...
The use of ring polymer molecular dynamics (RPMD) for the direct simulation of electron transfer (ET...
We demonstrate that the ring-polymer molecular dynamics (RPMD) method is equivalent to an automated ...
We extend ring-polymer molecular dynamics (RPMD) to allow for the direct simulation of general, elec...
We investigate the performance of the recently developed kinetically-constrained ring polymer molecu...
We take the golden-rule instanton method derived in the previous paper [J. O. Richardson, R. Bauer, ...
100 pagesThe transfer of electrons from one entity to another, the former – the electron donor and t...
Understanding the mechanisms and timescales of charge and energy transfer processes in large, comple...
The coupled transfer of electrons and protons is a central feature of biological and molecular catal...
The semiclassical instanton expression for the tunneling splitting between two symmetric wells is re...
We address the calculation of microcanonical reaction rates for processes involving significant nucl...
This thesis presents the ring polymer molecular dynamics (RPMD) approximation to the Kubo-transforme...
We apply Thermostatted Ring Polymer Molecular Dynamics (TRPMD), a recently-proposed approximate quan...
Ring polymer molecular dynamics (RPMD) is used to directly simulate the injection and relaxation of ...
A partial linearized path integral approach is used to calculate the condensed phase electron transf...
The thermal rate constants of two prototypical insertion-type reactions, namely, N/O + H<sub>2</sub>...