Litcius/Paper detail

Learning local and semi-local density functionals from exact exchange-correlation potentials and energies

Bikash Kanungo, Jeffrey Hatch, Paul M. Zimmerman, Vikram Gavini

2025Science Advances7 citationsDOIOpen Access PDF

Abstract

Finding accurate exchange-correlation (XC) functionals remains the defining challenge in density functional theory (DFT). Despite 40 years of active development, attaining general purpose chemical accuracy is still elusive with existing functionals. We present a data-driven pathway to learn the XC functional by using the exact density, XC energy, and XC potential. While the exact densities are obtained from accurate configuration interaction (CI), the exact XC energies and XC potentials are obtained via inverse DFT calculations on the CI densities. We demonstrate how simple neural network (NN)-based local density approximation (LDA) and generalized gradient approximation (GGA), trained on just five atoms and two molecules, provide remarkable improvement in total energies and densities. Particularly, the NN-based GGA functional attains similar accuracy as the higher rung SCAN meta-GGA on various thermochemistry datasets. These results underscore the promise of using the XC potential in modeling XC functionals and can pave the way for systematic learning of increasingly accurate XC functionals.

Topics & Concepts

Density functional theoryThermochemistrySimple (philosophy)Local-density approximationPhysicsInverseOrbital-free density functional theoryHybrid functionalStatistical physicsInverse problemArtificial neural networkFunctional theoryExact solutions in general relativityEnergy (signal processing)Quantum mechanicsTime-dependent density functional theoryElectronic structureKohn–Sham equationsApplied mathematicsTotal energyMachine Learning in Materials ScienceComputational Drug Discovery MethodsAdvanced Chemical Physics Studies