English

A Deterministic Framework for Neural Network Quantum States in Quantum Chemistry

Chemical Physics 2026-05-12 v2 Quantum Physics

Abstract

We present a deterministic optimization framework for Neural Network Quantum States (NQS) designed to bypass the sampling variance and slow mixing issues inherent in stochastic optimization. By projecting a neural backflow ansatz onto dynamically evolving configuration subspaces and applying a post-hoc second-order perturbative correction, our method provides a systematic route for optimizing the selected variational component of the wavefunction and estimating residual correlation through a post-hoc perturbative correction. The implementation utilizes a hybrid CPU-GPU architecture that shows empirical sub-linear wall-time scaling with respect to the subspace size over the tested range, enabling the calculation of strongly correlated systems, such as the chromium dimer, within Hilbert spaces of 102310^{23} configurations. Benchmarks on molecular bond dissociations demonstrate that this deterministic approach yields stable convergence and accuracies comparable to selected reference methods in the tested systems.

Keywords

Cite

@article{arxiv.2601.21310,
  title  = {A Deterministic Framework for Neural Network Quantum States in Quantum Chemistry},
  author = {Zheng Che},
  journal= {arXiv preprint arXiv:2601.21310},
  year   = {2026}
}
R2 v1 2026-07-01T09:25:05.963Z