Solvent-mediated PMF from HNC-OZ equations expressed as convolution of generalised excluded volume functions, recovering Asakura-Oosawa for hard cores and accurate for DPD ultrasoft systems.
Metadensity functional learning for classical fluids: Regularizing with pair correlations
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abstract
We investigate and exploit consequences of the recent neural metadensity functional theory [Kampa et al., Phys. Rev. Lett. 134, 107301 (2025), 10.1103/PhysRevLett.134.107301] for describing the physics of inhomogeneous fluids. The metadensity dependence on the pair potential is relevant for soft matter design and Henderson inversion and it allows one to change the pair potential on the fly at prediction stage. Here we consider one-dimensional systems with short-ranged (truncated) interparticle forces and draw on the functional pair potential dependence to investigate 'metadirect' routes towards the bulk fluid pair correlation structure. Classical density functional theory provides the required functional relationships. Efficient variational calculus is implemented by neural functional line integration and automatic differentiation. We regularize local learning of neural functionals by comparing the pair structure from different routes. Thereby results from metadirect functional differentiation are matched against accurate test particle data from an initial locally trained metadensity functional. Accessing the pair structure via the metadensity functional dependence circumvents Ornstein-Zernike inversion and it is based on first principles.
years
2026 2verdicts
UNVERDICTED 2representative citing papers
Extends gauge invariance via operator shifting in quantum statistical mechanics, deriving sum rules and hyperdensity functionals for equilibrium and nonequilibrium cases.
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Approximate additivity in the solvent-mediated potential of mean force for ultrasoft particle systems
Solvent-mediated PMF from HNC-OZ equations expressed as convolution of generalised excluded volume functions, recovering Asakura-Oosawa for hard cores and accurate for DPD ultrasoft systems.
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Quantum statistical mechanics: Gauge invariance, operator shifting, hyperdensity functionals, and nonequilibrium sum rules
Extends gauge invariance via operator shifting in quantum statistical mechanics, deriving sum rules and hyperdensity functionals for equilibrium and nonequilibrium cases.