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A deep equivariant neural network approach for efficient hybrid density functional calculations

Zechen Tang, He Li, Peize Lin, Xiaoxun Gong, Gan Jin, Lixin He, Hong Jiang, Xinguo Ren, Wenhui Duan, Yong Xu

2024Nature Communications32 citationsDOIOpen Access PDF

Abstract

Hybrid density functional calculations are essential for accurate description of electronic structure, yet their widespread use is restricted by the substantial computational cost. Here we develop DeepH-hybrid, a deep equivariant neural network method for learning the hybrid-functional Hamiltonian as a function of material structure, which circumvents the time-consuming self-consistent field iterations and enables the study of large-scale materials with hybrid-functional accuracy. Our extensive experiments demonstrate good reliability as well as effective transferability and efficiency of the method. As a notable application, DeepH-hybrid is applied to study large-supercell Moiré-twisted materials, offering the first case study on how the inclusion of exact exchange affects flat bands in magic-angle twisted bilayer graphene. The work generalizes deep-learning electronic structure methods to beyond conventional density functional theory, facilitating the development of deep-learning-based ab initio methods. Hybrid density functionals are crucial for accurate materials calculations, yet their application is limited by the computational cost. Here, authors overcome this efficiency bottleneck through deep learning, enabling large-scale hybrid density functional calculations.

Topics & Concepts

Equivariant mapComputer scienceArtificial neural networkDeep neural networksDensity functional theoryArtificial intelligencePhysicsMathematicsPure mathematicsQuantum mechanicsMachine Learning in Materials ScienceX-ray Diffraction in CrystallographyCatalysis and Oxidation Reactions