Extended norm-conserving pseudopotentials

Abstract

Atomic pseudopotentials simplify electronic calculations by eliminating atomic core levels and the potentials that bind them. Outside some core radius, norm-conserving pseudopotentials produce the same scattering properties (radial logarithmic derivatives of wave functions for angular momenta of interest) as full-atomic potentials to zeroth and first order in energy about valence-level eigenvalues. We extend the correctness of the radial logarithmic derivative one order further in energy and present analytic and numerical results showing that this extension improves higher-order energy derivatives as well. We also show how our change improves predictions of excited single-particle eigenvalues in a wide variety of atoms, as well as high-energy scattering properties, with effects visible in a band-structure calculation. Our potentials converge nearly as quickly in reciprocal space as the Vanderbilt (modified Hamann-Schl\"uter-Chiang) potentials from which they are derived, and are easily generated.

Keywords

PhysicsEigenvalues and eigenvectorsScatteringWave functionValence (chemistry)LogarithmQuantum mechanicsExcited stateLogarithmic derivativeAtomic physicsMathematical analysisMathematics

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Publication Info

Year: 1989
Type: article
Volume: 40
Issue: 6
Pages: 3652-3660
Citations: 138
Access: Closed

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APA Style

                            
                                
                                    Eric L. Shirley, 
                                
                                    Douglas C. Allan, 
                                
                                    Richard M. Martin
                                
                                et al.
                            
                            (1989). 
                            Extended norm-conserving pseudopotentials. 
                            Physical review. B, Condensed matter
                            , 40
                            (6)
                            , 3652-3660.
                            https://doi.org/10.1103/physrevb.40.3652
                        

Identifiers

DOI: 10.1103/physrevb.40.3652
PMID: 9992335

Data Quality

Data completeness: 81%