Efficient optimization of neural network backflow for ab-initio quantum chemistry

• URL: http://arxiv.org/abs/2502.18843v1
• Date: Wed, 26 Feb 2025 05:31:08 GMT
• Title: Efficient optimization of neural network backflow for ab-initio quantum chemistry
• Authors: An-Jun Liu, Bryan K. Clark,
• Abstract summary: Ground state of second-quantized quantum chemistry Hamiltonians is key to determining molecular properties.<n>We develop improvements for optimizing these wave-functions which includes compact subspace construction, truncated local energy evaluations, improved sampling, and physics-informed modifications.<n>An ablation study highlights the contribution of each enhancement, showing significant gains in energy accuracy and computational efficiency.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: The ground state of second-quantized quantum chemistry Hamiltonians is key to determining molecular properties. Neural quantum states (NQS) offer flexible and expressive wavefunction ansatze for this task but face two main challenges: highly peaked ground-state wavefunctions hinder efficient sampling, and local energy evaluations scale quartically with system size, incurring significant computational costs. In this work, we develop algorithmic improvements for optimizing these wave-functions which includes compact subspace construction, truncated local energy evaluations, improved stochastic sampling, and physics-informed modifications. We apply these improvements to the neural network backflow (NNBF) ansatz finding that they lead to improved accuracy and scalability. Using these techniques, we find NNBF surpasses traditional methods like CCSD and CCSD(T), outperform existing NQS approaches, and achieve competitive energies compared to state-of-the-art quantum chemistry methods such as HCI, ASCI, and FCIQMC. An ablation study highlights the contribution of each enhancement, showing significant gains in energy accuracy and computational efficiency. We also examine the dependence of NNBF expressiveness on the inverse participation ratio (IPR), observing that more delocalized states are generally harder to approximate.

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