Repository landing page
Efficient and Deterministic Propagation of Mixed Quantum-Classical Liouville Dynamics
Abstract
We propose a highly efficient mixed quantum-classical molecular dynamics scheme based on a solution of the quantum-classical Liouville equation (QCLE). By casting the equations of motion for the quantum subsystem and classical bath degrees of freedom onto an approximate set of coupled first-order differential equations for <i>c</i>-numbers, this scheme propagates the composite system in time deterministically in terms of independent classical-like trajectories. To demonstrate its performance, we apply the method to the spin-boson model, a photoinduced electron transfer model, and a Fenna–Matthews–Olsen complex model, and find excellent agreement out to long times with the numerically exact results, using several orders of magnitude fewer trajectories than surface-hopping solutions of the QCLE. Owing to its accuracy and efficiency, this method promises to be very useful for studying the dynamics of mixed quantum-classical systems- Text
- Journal contribution
- Biophysics
- Space Science
- Biological Sciences not elsewhere classified
- Mathematical Sciences not elsewhere classified
- Chemical Sciences not elsewhere classified
- Physical Sciences not elsewhere classified
- Information Systems not elsewhere classified
- time deterministically
- bath degrees
- QCLE
- quantum subsystem
- surface-hopping solutions
- Deterministic Propagation
- Mixed Quantum-Classical Liouville Dynamics
- method
- photoinduced electron transfer model
- quantum-classical Liouville equation
- classical-like trajectories
- spin-boson model
- scheme propagates
- dynamics scheme
- quantum-classical systems