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Optimizing design choices for neural quantum states

Moritz Reh, Markus Schmitt, Martin Gärttner

2023Physical review. B./Physical review. B51 citationsDOI

Abstract

Neural quantum states are a new family of variational Ans\"atze for quantum-many body wave functions with advantageous properties in the notoriously challenging case of two spatial dimensions. Since their introduction, a wide variety of different network architectures have been employed to study paradigmatic models in quantum many-body physics with a particular focus on quantum spin models. Nonetheless, many questions remain about the effect that the choice of architecture has on the performance on a given task. In this work, we present a unified comparison of a selection of popular network architectures and symmetrization schemes employed for ground-state searches of prototypical spin Hamiltonians, namely, the two-dimensional transverse-field Ising model and the ${J}_{1}\text{\ensuremath{-}}{J}_{2}$ model. In the presence of a nontrivial sign structure of the ground states, we find that the details of symmetrization crucially influence the performance. We describe this effect in detail and discuss its consequences, especially for autoregressive models, as their direct sampling procedure is not compatible with the symmetrization procedure that we found to be optimal.

Topics & Concepts

SymmetrizationQuantumIsing modelComputer scienceArtificial neural networkVariety (cybernetics)Statistical physicsPhysicsTheoretical computer scienceMathematicsQuantum mechanicsArtificial intelligenceMathematical analysisQuantum many-body systemsQuantum Computing Algorithms and ArchitectureNeural Networks and Reservoir Computing
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