Million-scale data integrated deep neural network for phonon properties of heuslers spanning the periodic table

Existing machine learning potentials for predicting phonon properties of crystals are typically limited on a material-to-material basis, primarily due to the exponential scaling of model complexity with the number of atomic species. We address this bottleneck with the developed Elemental Spatial Density Neural Network Force Field, namely Elemental-SDNNFF. The effectiveness and precision of our Elemental-SDNNFF approach are demonstrated on 11,866 full, half, and quaternary Heusler structures spanning 55 elements in the periodic table by prediction of complete phonon properties. Self-improvement schemes including active learning and data augmentation techniques provide an abundant 9.4 million atomic data for training. Deep insight into predicted ultralow lattice thermal conductivity (

Million-scale data integrated deep neural network for phonon properties of heuslers spanning the periodic table

Plasmonic effects in the neutralization of slow ions at a metallic surface

Constructing periodic orbits of high-dimensional chaotic systems by an adjoint-based variational method

Modeling the Ga/As binary system across temperatures and compositions from first principles

Plasmonic effects in the neutralization of slow ions at a metallic surface

Constructing periodic orbits of high-dimensional chaotic systems by an adjoint-based variational method

Modeling the Ga/As binary system across temperatures and compositions from first principles