Litcius/Paper detail

Correlation-enhanced neural networks as interpretable variational quantum states

Agnes Valenti, Eliška Greplová, Netanel H. Lindner, Sebastian D. Huber

2022Physical Review Research24 citationsDOIOpen Access PDF

Abstract

Variational methods have proven to be excellent tools to approximate the ground states of complex many-body Hamiltonians. Generic tools such as neural networks are extremely powerful, but their parameters are not necessarily physically motivated. Thus, an efficient parametrization of the wave function can become challenging. In this Letter we introduce a neural-network-based variational ansatz that retains the flexibility of these generic methods while allowing for a tunability with respect to the relevant correlations governing the physics of the system. We illustrate the success of this approach on topological, long-range correlated, and frustrated models. Additionally, we introduce compatible variational optimization methods for the exploration of low-lying excited states without symmetries that preserve the interpretability of the ansatz.

Topics & Concepts

AnsatzInterpretabilityWave functionArtificial neural networkParametrization (atmospheric modeling)Flexibility (engineering)Homogeneous spaceRange (aeronautics)QuantumComputer scienceStatistical physicsExcited stateTopology (electrical circuits)PhysicsMathematicsQuantum mechanicsArtificial intelligenceEngineeringRadiative transferCombinatoricsAerospace engineeringGeometryStatisticsQuantum many-body systemsModel Reduction and Neural NetworksQuantum, superfluid, helium dynamics