Huajie Chen, Xiaoying Dai, Xingao Gong, Lianhua He, Aihui Zhou
Published 2013-02-27, updated 2013-11-21Version 3
The Kohn-Sham equation is a powerful, widely used approach for computation of ground state electronic energies and densities in chemistry, materials science, biology, and nanosciences. In this paper, we study the adaptive finite element approximations for the Kohn-Sham model. Based on the residual type a posteriori error estimators proposed in this paper, we introduce an adaptive finite element algorithm with a quite general marking strategy and prove the convergence of the adaptive finite element approximations. Using D{\" o}rfler's marking strategy, we then get the convergence rate and quasi-optimal complexity. We also carry out several typical numerical experiments that not only support our theory,but also show the robustness and efficiency of the adaptive finite element computations in electronic structure calculations.
Comments: 38pages, 7figures
Convergence of Adaptive Finite Element Approximations for Nonlinear Eigenvalue Problems
Reliable a-posteriori error estimators for $hp$-adaptive finite element approximations of eigenvalue/eigenvector problems
Numerical analysis of the planewave discretization of some orbital-free and Kohn-Sham models
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