Implementing advanced trial wave functions in fermion quantum Monte Carlo via stochastic sampling

TL;DR

This paper presents a new stochastic sampling approach to implement complex correlated trial wave functions in fermion quantum Monte Carlo, significantly improving accuracy and efficiency in molecular ground-state energy calculations.

Contribution

It introduces a method to incorporate multi-dimensional integral wave functions as trial states in AFQMC using generalized Metropolis sampling, enhancing the method's flexibility and performance.

Findings

Achieves chemical accuracy in molecular ground-state energies

Improves both accuracy and efficiency over traditional trial wave functions

Maintains low-polynomial computational scaling in AFQMC

Abstract

We introduce an efficient approach to implement correlated many-body trial wave functions in auxiliary-field quantum Monte Carlo (AFQMC). To control the sign/phase problem in AFQMC, a constraint is derived from an exact gauge condition but is typically imposed approximately through a trial wave function or trial density matrix, whose quality can affect the accuracy of the method. Furthermore, the trial wave function can also affect the efficiency through importance sampling. The most natural form of the trial wave function has been single Slater determinants or their linear combinations. More sophisticated forms, for example, with the inclusion of a Jastrow factor or other explicit correlations, have been challenging to use and their implementation is often assumed to require a quantum computer. In this work, we demonstrate that a large class of correlated wave functions, written in the general form of multi-dimensional integrals over hidden or auxiliary variables times Slater determinants, can be implemented as trial wave function by coupling the random walkers to a generalized Metropolis sampling. We discuss the fidelity of AFQMC with stochastically sampled trial wave functions, which are relevant to both quantum and classical algorithms. We illustrate the method and show that an efficient implementation can be achieved which preserves the low-polynomial computational scaling of AFQMC. We test our method in molecules under bond stretching and in transition metal diatomics. Significant improvements are seen in both accuracy and efficiency over typical trial wave functions, and the method yields total ground-state energies systematically within chemical accuracy. The method can be useful for incorporating other advanced wave functions, for example, neural quantum state wave functions optimized from machine learning techniques, or for other forms of fermion quantum Monte Carlo.