Exact thermal density functional theory for a model system: Correlation components and accuracy of the zero-temperature exchange-correlation approximation - Concepedia

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Exact thermal density functional theory for a model system: Correlation components and accuracy of the zero-temperature exchange-correlation approximation

DOI Full Paper Access

47

Citations

54

References

2016

Year

Justin C. Smith, Aurora Pribram−Jones, Kieron Burke

Physical review. B./Physical review. B

Free EnergyQuantum Lattice SystemEngineeringMany-body Quantum PhysicComputational ChemistryChemistryThermal EnergyThermodynamic ModellingAsymmetric Hubbard DimerMany-body ProblemNumerical SimulationThermodynamicsThermal ModelingQuantum SciencePhysicsQuantum Field TheoryQuantum ChemistryHeat TransferEntropyNatural SciencesCondensed Matter PhysicsApplied PhysicsZero-temperature Exchange-correlation ApproximationModel SystemDisordered Quantum SystemLattice Field TheoryWeak CorrelationCorrelation ComponentsThermal EngineeringMultiscale Modeling

Abstract

Thermal density functional theory calculations often use the Mermin-Kohn-Sham scheme, but employ ground-state approximations to the exchange-correlation (XC) free energy. In the simplest solvable nontrivial model, an asymmetric Hubbard dimer, we calculate the exact many-body energies and the exact Mermin-Kohn-Sham functionals for this system and extract the exact XC free energy. For moderate temperatures and weak correlation, we find this approximation to be excellent. We extract various exact free-energy correlation components and the exact adiabatic connection formula.

References

	Year	Citations

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