Gu Qiangqiang, Zhouyin Zhanghao, Pandey Shishir Kumar, Zhang Peng, Zhang Linfeng, E Weinan
AI for Science Institute, 100080, Beijing, China.
School of Mathematical Science, Peking University, 100871, Beijing, China.
Nat Commun. 2024 Aug 8;15(1):6772. doi: 10.1038/s41467-024-51006-4.
Simulating electronic behavior in materials and devices with realistic large system sizes remains a formidable task within the ab initio framework due to its computational intensity. Here we show DeePTB, an efficient deep learning-based tight-binding approach with ab initio accuracy to address this issue. By training on structural data and corresponding ab initio eigenvalues, the DeePTB model can efficiently predict tight-binding Hamiltonians for unseen structures, enabling efficient simulations of large-size systems under external perturbations such as finite temperatures and strain. This capability is vital for semiconductor band gap engineering and materials design. When combined with molecular dynamics, DeePTB facilitates efficient and accurate finite-temperature simulations of both atomic and electronic behavior simultaneously. This is demonstrated by computing the temperature-dependent electronic properties of a gallium phosphide system with 10 atoms. The availability of DeePTB bridges the gap between accuracy and scalability in electronic simulations, potentially advancing materials science and related fields by enabling large-scale electronic structure calculations.
由于计算强度大,在从头算框架内模拟具有实际大系统规模的材料和器件中的电子行为仍然是一项艰巨的任务。在此,我们展示了DeePTB,这是一种基于深度学习的高效紧束缚方法,具有从头算精度,可解决此问题。通过对结构数据和相应的从头算本征值进行训练,DeePTB模型可以有效地预测未见结构的紧束缚哈密顿量,从而能够在诸如有限温度和应变等外部扰动下对大尺寸系统进行高效模拟。这种能力对于半导体带隙工程和材料设计至关重要。当与分子动力学相结合时,DeePTB有助于同时对原子和电子行为进行高效且准确的有限温度模拟。通过计算具有10个原子的磷化镓系统的温度相关电子性质,证明了这一点。DeePTB的可用性弥合了电子模拟中精度和可扩展性之间的差距,通过实现大规模电子结构计算,有可能推动材料科学及相关领域的发展。
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