Tangent-plane epistemic uncertainty for projected spin forces improves active learning selection and prediction accuracy in magnetic machine-learning interatomic potentials.
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Pith papers citing it
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2026 3verdicts
UNVERDICTED 3representative citing papers
Elastic strain reversibly reorganizes threading dislocations in GaN, enhancing thermal conductivity by 23% at 0.21% strain via reduced phonon scattering from changed dislocation correlations.
Tunneling splittings for H and D in bcc Nb match experiment only in a 5D nonadiabatic lattice-renormalized Born-Oppenheimer model; adiabatic separation holds solely in the muon mass limit.
citing papers explorer
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Tangent-Plane Evidential Uncertainty in Active Learning for Magnetic Interatomic Potentials
Tangent-plane epistemic uncertainty for projected spin forces improves active learning selection and prediction accuracy in magnetic machine-learning interatomic potentials.
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Reversible Modulation of Thermal Conductivity in GaN via Strain-Driven Reorganization of Dislocation Ensembles
Elastic strain reversibly reorganizes threading dislocations in GaN, enhancing thermal conductivity by 23% at 0.21% strain via reduced phonon scattering from changed dislocation correlations.
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Transition-state lattice modes and the breakdown of adiabatic tunneling for hydrogen and deuterium in bcc Nb
Tunneling splittings for H and D in bcc Nb match experiment only in a 5D nonadiabatic lattice-renormalized Born-Oppenheimer model; adiabatic separation holds solely in the muon mass limit.