Efficient Quantum Simulation of Non-Adiabatic Molecular Dynamics with Precise Electronic Structure

TL;DR

This paper presents a quantum-adapted extension to non-adiabatic molecular dynamics that enhances the calculation of potential energy surfaces with high precision, enabling efficient quantum simulations of complex chemical processes.

Contribution

It introduces a novel quantum-compatible surface hopping method with curvature corrections and a high-accuracy PES protocol adaptable to diverse chemical systems.

Findings

Supports active space selection for PES calculations

Enables parallel acceleration on quantum and classical clusters

Demonstrates applicability to charged H3+ and C2H4 systems

Abstract

In the study of non-adiabatic chemical processes such as photocatalysis and photosynthesis, non-adiabatic molecular dynamics (NAMD) is an indispensable theoretical tool, which requires precise potential energy surfaces (PESs) of ground and excited states. Quantum computing offers promising potential for calculating PESs that are intractable for classical computers. However, its realistic application poses significant challenges to the development of quantum algorithms that are sufficiently general to enable efficient and precise PES calculations across chemical systems with diverse properties, as well as to seamlessly adapt existing NAMD theories to quantum computing. In this work, we introduce a quantum-adapted extension to the Landau-Zener-Surface-Hopping (LZSH) NAMD. This extension incorporates curvature-driven hopping corrections that protect the population evolution while maintaining the efficiency gained from avoiding the computation of non-adiabatic couplings (NACs), as well as preserving the trajectory independence that enables parallelization. Furthermore, to ensure the high-precision PESs required for surface hopping dynamics, we develop a sub-microhartree-accurate PES calculation protocol. This protocol supports active space selection, enables parallel acceleration either on quantum or classical clusters, and demonstrates adaptability to diverse chemical systems - including the charged H3+ ion and the C2H4 molecule, a prototypical multi-reference benchmark. This work paves the way for practical application of quantum computing in NAMD, showcasing the potential of parallel simulation on quantum-classical heterogeneous clusters for ab-initio computational chemistry.