Litcius/Paper detail

Deep Quantum Geometry of Matrices

Xizhi Han, Sean A. Hartnoll

2020Physical Review X29 citationsDOIOpen Access PDF

Abstract

We employ machine learning techniques to provide accurate variational wave functions for matrix quantum mechanics, with multiple bosonic and fermionic matrices. The variational quantum Monte Carlo method is implemented with deep generative flows to search for gauge-invariant low-energy states. The ground state (and also long-lived metastable states) of an SUN matrix quantum mechanics with three bosonic matrices, and also its supersymmetric "mini-BMN" extension, are studied as a function of coupling and N. Known semiclassical fuzzy sphere states are recovered, and the collapse of these geometries in more strongly quantum regimes is probed using the variational wave function. We then describe a factorization of the quantum mechanical Hilbert space that corresponds to a spatial partition of the emergent geometry. Under this partition, the fuzzy sphere states show a boundary-law entanglement entropy in the large N limit.

Topics & Concepts

PhysicsFuzzy sphereWave functionQuantum entanglementQuantum mechanicsQuantum Monte CarloQuantum geometryQuantum stateHilbert spaceQuantumQuantum algorithmQuantum operationSemiclassical physicsClassical mechanicsGround stateQuantum discordQuantum relative entropyPartition function (quantum field theory)Quantum dissipationWave function collapseQuantum processQuantum statistical mechanicsQuantum dynamicsOpen quantum systemStatistical physicsVariational methodQuantum informationMathematical physicsVariational Monte CarloMetastabilityDensity matrixQuantum many-body systemsQuantum chaos and dynamical systemsBlack Holes and Theoretical Physics