Related papers: Sorting Out Quantum Monte Carlo

Sorting Out Quantum Monte Carlo

URL: http://arxiv.org/abs/2311.05598v1
Date: Thu, 9 Nov 2023 18:56:43 GMT
Title: Sorting Out Quantum Monte Carlo
Authors: Jack Richter-Powell, Luca Thiede, Al\'an Asparu-Guzik, David Duvenaud
Abstract summary: Molecular modeling at the quantum level requires choosing a parameterization of the wavefunction that both respects the required particle symmetries. We introduce a new antisymmetrization layer derived from sorting, the $textitsortlet$, which scales as $O(N log N)$ with regards to the number of particles. We show numerically that applying this anti-symmeterization layer on top of an attention based neural-network backbone yields a flexible wavefunction parameterization.
Score: 15.0505667077874
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Molecular modeling at the quantum level requires choosing a parameterization of the wavefunction that both respects the required particle symmetries, and is scalable to systems of many particles. For the simulation of fermions, valid parameterizations must be antisymmetric with respect to the exchange of particles. Typically, antisymmetry is enforced by leveraging the anti-symmetry of determinants with respect to the exchange of matrix rows, but this involves computing a full determinant each time the wavefunction is evaluated. Instead, we introduce a new antisymmetrization layer derived from sorting, the $\textit{sortlet}$, which scales as $O(N \log N)$ with regards to the number of particles -- in contrast to $O(N^3)$ for the determinant. We show numerically that applying this anti-symmeterization layer on top of an attention based neural-network backbone yields a flexible wavefunction parameterization capable of reaching chemical accuracy when approximating the ground state of first-row atoms and small molecules.

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