CONVERGENCE OF THE PLANEWAVE APPROXIMATIONS FOR QUANTUM INCOMMENSURATE SYSTEMS

Authors

Ting Wang, Beijing Normal University
Huajie Chen, Beijing Normal University
Aihui Zhou, Institute of Computational Mathematics and Scientific-Engineering Computing, Chinese Academy of Sciences
Yuzhi Zhou, China Academy of Engineering Physics
Daniel Massatt, Louisiana State University

Document Type

Article

Publication Date

1-1-2025

Abstract

Incommensurate structures come from stacking the single layers of low dimensional materials on top of one another with misalignment such as a twist in orientation. While these structures are of significant physical interest, they pose many theoretical challenges due to the loss of periodicity. This paper studies the physical observables of continuum Schrodinger operators for incommensurate systems. We characterize the density of states and local density of states in real and reciprocal spaces, and develop novel numerical methods to approximate them. In particular, we (i) justify the thermodynamic limit of the density of states and local density of states via the operator kernel characterization; and (ii) propose efficient numerical schemes based on plane wave approximation and the trapezoidal rule in reciprocal space. We present both rigorous analysis and numerical simulations to support the reliability and efficiency of our numerical algorithms.

Publication Source (Journal or Book title)

Multiscale Modeling and Simulation

First Page

545

Last Page

576

Recommended Citation

Wang, T., Chen, H., Zhou, A., Zhou, Y., & Massatt, D. (2025). CONVERGENCE OF THE PLANEWAVE APPROXIMATIONS FOR QUANTUM INCOMMENSURATE SYSTEMS. Multiscale Modeling and Simulation, 23 (1), 545-576. https://doi.org/10.1137/23M1553650