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Restricted Boltzmann Machines for Quantum States with Non-Abelian or Anyonic Symmetries

Tom Vieijra, Corneel Casert, Jannes Nys, Wesley De Neve, Jutho Haegeman, J. Ryckebusch, Frank Verstraete

2020Physical Review Letters107 citationsDOIOpen Access PDF

Abstract

Although artificial neural networks have recently been proven to provide a promising new framework for constructing quantum many-body wave functions, the parametrization of a quantum wave function with non-abelian symmetries in terms of a Boltzmann machine inherently leads to biased results due to the basis dependence. We demonstrate that this problem can be overcome by sampling in the basis of irreducible representations instead of spins, for which the corresponding ansatz respects the non-abelian symmetries of the system. We apply our methodology to find the ground states of the one-dimensional antiferromagnetic Heisenberg (AFH) model with spin-1/2 and spin-1 degrees of freedom, and obtain a substantially higher accuracy than when using the s_{z} basis as an input to the neural network. The proposed ansatz can target excited states, which is illustrated by calculating the energy gap of the AFH model. We also generalize the framework to the case of anyonic spin chains.

Topics & Concepts

AnsatzPhysicsHomogeneous spaceSpin (aerodynamics)SpinsWave functionBasis (linear algebra)Quantum mechanicsQuantumQuantum numberBasis functionAbelian groupTheoretical physicsMathematicsPure mathematicsCondensed matter physicsThermodynamicsGeometryQuantum many-body systemsPhysics of Superconductivity and MagnetismQuantum and electron transport phenomena
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