Litcius/Paper detail

Machine learning method for tight-binding Hamiltonian parameterization from ab-initio band structure

Zifeng Wang, Shizhuo Ye, Hao Wang, Jin He, Qijun Huang, Sheng Chang

2021npj Computational Materials73 citationsDOIOpen Access PDF

Abstract

Abstract The tight-binding (TB) method is an ideal candidate for determining electronic and transport properties for a large-scale system. It describes the system as real-space Hamiltonian matrices expressed on a manageable number of parameters, leading to substantially lower computational costs than the ab-initio methods. Since the whole system is defined by the parameterization scheme, the choice of the TB parameters decides the reliability of the TB calculations. The typical empirical TB method uses the TB parameters directly from the existing parameter sets, which hardly reproduces the desired electronic structures quantitatively without specific optimizations. It is thus not suitable for quantitative studies like the transport property calculations. The ab-initio TB method derives the TB parameters from the ab-initio results through the transformation of basis functions, which achieves much higher numerical accuracy. However, it assumes prior knowledge of the basis and may encompass truncation error. Here, a machine learning method for TB Hamiltonian parameterization is proposed, within which a neural network (NN) is introduced with its neurons acting as the TB matrix elements. This method can construct the empirical TB model that reproduces the given ab-initio energy bands with predefined accuracy, which provides a fast and convenient way for TB model construction and gives insights into machine learning applications in physical problems.

Topics & Concepts

Ab initioHamiltonian (control theory)Computer scienceTight bindingAb initio quantum chemistry methodsStatistical physicsArtificial neural networkAlgorithmElectronic structureApplied mathematicsArtificial intelligenceMathematicsMathematical optimizationPhysicsQuantum mechanicsMoleculeMachine Learning in Materials ScienceFerroelectric and Negative Capacitance DevicesFuel Cells and Related Materials