Litcius/Paper detail

Machine learning of consistent thermodynamic models using automatic differentiation

David Rosenberger, Kipton Barros, Timothy C. Germann, Nicholas Lubbers

2022Physical review. E32 citationsDOIOpen Access PDF

Abstract

We propose a data-driven method to describe consistent equations of state (EOS) for arbitrary systems. Complex EOS are traditionally obtained by fitting suitable analytical expressions to thermophysical data. A key aspect of EOS is that the relationships between state variables are given by derivatives of the system free energy. In this work, we model the free energy with an artificial neural network and utilize automatic differentiation to directly learn the derivatives of the free energy. We demonstrate this approach on two different systems, the analytic van der Waals EOS and published data for the Lennard-Jones fluid, and we show that it is advantageous over direct learning of thermodynamic properties (i.e., not as derivatives of the free energy but as independent properties), in terms of both accuracy and the exact preservation of the Maxwell relations. Furthermore, the method implicitly provides the free energy of a system without explicit integration.

Topics & Concepts

Thermodynamic integrationvan der Waals forceEquation of stateArtificial neural networkWork (physics)Energy (signal processing)Computer scienceKey (lock)Statistical physicsVan der Waals equationState (computer science)Experimental dataAutomatic differentiationArtificial intelligenceThermodynamicsPhysicsAlgorithmMathematicsComputationQuantum mechanicsStatisticsComputer securityMoleculeMachine Learning in Materials ScienceProtein Structure and DynamicsPhase Equilibria and Thermodynamics