Observable Error Bounds of the Time-splitting Scheme for Quantum-Classical Molecular Dynamics

08/18/2021
by   Di Fang, et al.
0

Quantum-classical molecular dynamics, as a partial classical limit of the full quantum Schrödinger equation, is a widely used framework for quantum molecular dynamics. The underlying equations are nonlinear in nature, containing a quantum part (represents the electrons) and a classical part (stands for the nuclei). An accurate simulation of the wave function typically requires a time step comparable to the rescaled Planck constant h, resulting in a formidable cost when h≪ 1. We prove an additive observable error bound of Schwartz observables for the proposed time-splitting schemes based on semiclassical analysis, which decreases as h becomes smaller. Furthermore, we establish a uniform-in-h observable error bound, which allows an 𝒪(1) time step to accurately capture the physical observable regardless of the size of h. Numerical results verify our estimates.

READ FULL TEXT

Please sign up or login with your details

Forgot password? Click here to reset