Add to ORKGWe propose an algorithm for accurate, systematic, and scalable computation of interatomic forces within the auxiliary-field quantum Monte Carlo (AFQMC) method. The algorithm relies on the Hellmann-Feynman theorem and incorporates Pulay corrections in the presence of atomic orbital basis sets. We benchmark the method for small molecules by comparing the computed forces with the derivatives of the AFQMC potential energy surface and by direct comparison with other quantum chemistry methods. We then perform geometry optimizations using the steepest descent algorithm in larger molecules. With realistic basis sets, we obtain equilibrium geometries in agreement, within statistical error bars, with experimental values. The increase in computational...
Highly accurate force fields are a mandatory requirement to generate predictive simulations. Here we...
We develop a local correlation variant of auxiliary field quantum Monte Carlo (AFQMC) that is based ...
We present an efficient scheme for parametrizing complex molecule-surface force fields from ab initi...
We propose an algorithm for accurate, systematic, and scalable computation of interatomic forces wit...
In order to overcome the difficulty of optimizing molecular geometry using quantum Monte Carlo metho...
We describe an efficient algorithm to compute forces in quantum Monte Carlo using adjoint algorithmi...
We develop a formalism to directly evaluate the matrix of force constants within a Quantum Monte Car...
Quantum Monte Carlo (QMC) is one of the most promising methods for solving quantum many-body proble...
The auxiliary‐field quantum Monte Carlo (AFQMC) method provides a computational framework for solvin...
The demands on the accuracy of force fields for classical molecular dynamics simulations are steadil...
Diffusion Monte Carlo (DMC) is one of the most accurate techniques available for calculating the ele...
Molecular dynamics (MD) simulations employing classical force fields constitute the cornerstone of c...
Determining the accurate structure of a material is a critical step in understanding its physics. St...
While the computation of interatomic forces has become a well-established practice within variationa...
The quality of molecular dynamics simulations strongly depends on the accuracy of the underlying for...
Highly accurate force fields are a mandatory requirement to generate predictive simulations. Here we...
We develop a local correlation variant of auxiliary field quantum Monte Carlo (AFQMC) that is based ...
We present an efficient scheme for parametrizing complex molecule-surface force fields from ab initi...
We propose an algorithm for accurate, systematic, and scalable computation of interatomic forces wit...
In order to overcome the difficulty of optimizing molecular geometry using quantum Monte Carlo metho...
We describe an efficient algorithm to compute forces in quantum Monte Carlo using adjoint algorithmi...
We develop a formalism to directly evaluate the matrix of force constants within a Quantum Monte Car...
Quantum Monte Carlo (QMC) is one of the most promising methods for solving quantum many-body proble...
The auxiliary‐field quantum Monte Carlo (AFQMC) method provides a computational framework for solvin...
The demands on the accuracy of force fields for classical molecular dynamics simulations are steadil...
Diffusion Monte Carlo (DMC) is one of the most accurate techniques available for calculating the ele...
Molecular dynamics (MD) simulations employing classical force fields constitute the cornerstone of c...
Determining the accurate structure of a material is a critical step in understanding its physics. St...
While the computation of interatomic forces has become a well-established practice within variationa...
The quality of molecular dynamics simulations strongly depends on the accuracy of the underlying for...
Highly accurate force fields are a mandatory requirement to generate predictive simulations. Here we...
We develop a local correlation variant of auxiliary field quantum Monte Carlo (AFQMC) that is based ...
We present an efficient scheme for parametrizing complex molecule-surface force fields from ab initi...