Quantum dynamics simulations using Gaussian wavepackets: the vMCG method

IF 2.5 2区化学 Q3 CHEMISTRY, PHYSICAL

International Reviews in Physical Chemistry Pub Date : 2015-04-03 DOI:10.1080/0144235X.2015.1051354

Gareth W Richings, I. Polyak, K. E. Spinlove, Graham A Worth, I. Burghardt, B. Lasorne

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引用次数: 179

Abstract

Gaussian wavepacket methods are an attractive way to solve the time-dependent Schrödinger equation (TDSE). They have an underlying trajectory picture that has a natural connection to semi-classical mechanics, allowing a simple pictorial interpretation of an evolving wavepacket. They also have better scaling with system size compared to conventional grid-based techniques. Here we review the variational multi-configurational Gaussian (vMCG) method. This is a variational solution to the TDSE, with explicit coupling between the Gaussian basis functions, resulting in a favourable convergence on the exact solution. The implementation of the method and its performance will be discussed with examples from non-adiabatic photo-excited dynamics and tunneling to show that it can correctly describe both of these strongly quantum mechanical processes. Particular emphasis is given to the implementation of the direct dynamics variant, DD-vMCG, where the potential surfaces are calculated on-the-fly via an interface to quantum chemistry programs.

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使用高斯波包的量子动力学模拟:vMCG方法

高斯波包方法是求解时间相关Schrödinger方程(TDSE)的一种有吸引力的方法。他们有一个潜在的轨迹图，与半经典力学有自然的联系，允许对演进的波包进行简单的图像解释。与传统的基于网格的技术相比，它们还具有更好的系统大小可伸缩性。本文综述了变分多构型高斯(vMCG)方法。这是TDSE的变分解，高斯基函数之间显式耦合，导致精确解的有利收敛。本文将以非绝热光激发动力学和隧道效应为例讨论该方法的实现及其性能，以证明该方法可以正确地描述这两个强量子力学过程。特别强调了直接动力学变体DD-vMCG的实现，其中通过量子化学程序的接口实时计算潜在表面。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Reviews in Physical Chemistry 化学-物理化学

CiteScore

14.20

自引率

1.60%

发文量

审稿时长

1 months

期刊介绍： International Reviews in Physical Chemistry publishes review articles describing frontier research areas in physical chemistry. Internationally renowned scientists describe their own research in the wider context of the field. The articles are of interest not only to specialists but also to those wishing to read general and authoritative accounts of recent developments in physical chemistry, chemical physics and theoretical chemistry. The journal appeals to research workers, lecturers and research students alike.