Abstract
A recently published scheme for obtaining an approximate solution of the Dirac-Hartree-Fock equations for an atom is adapted and applied to the related Dirac-Slater problem. For a given $\mathrm{nl}$, one solves explicitly only for one large component orbital instead of the four determined in the Dirac-Slater calculations. The equation for this single component is closely akin to the Pauli equation. [We find that the Pauli mass-velocity and Darwin operators are accurate to only zeroth (instead of first) order in $\frac{(E\ensuremath{-}V)}{{c}^{2}}$. We present forms which are accurate to first order for cases in which the expansion in $\frac{(E\ensuremath{-}V)}{{c}^{2}}$ is valid.] Atomic calculations for uranium and plutonium demonstrate that this approximate method yields eigenvalues, eigenfunctions, spin-orbit parameters, and excitation energies in close agreement with the Dirac-Slater results. The method can be incorporated into existing nonrelativistic molecular and energy-band computer programs (such as those for the molecular scattered-wave method and the KKR and APW energy-band methods). This would then permit nearly relativistic solutions of the related problems without the complications introduced by the four-component-type solutions. We discuss implementation of the method for the scattered wave and APW methods.
Keywords
Hamiltonian (control theory)PhysicsEigenfunctionEigenvalues and eigenvectorsDirac equationPauli exclusion principleQuantum mechanicsSlater determinantDirac (video compression format)Mathematical physicsAtomic orbitalMathematicsNeutrino
Affiliated Institutions
Related Publications
An efficient numerical multicenter basis set for molecular orbital calculations: Application to FeCl4
The use of numerical solutions to atomlike single site potentials as a basis for molecular orbital calculations is investigated. The atomic Hamiltonian is modified by addition o...
A new computational approach to Slater’s SCF–<i>X</i>α equation
A new computational scheme is presented for the performance of LCAO−MO calculations in the SCF−Xα model. The scheme is intended to be applicable for large systems and to be more...
Generalized Kohn-Sham theory for electronic excitations in realistic systems
Instead of expressing the total energy of an interacting electron system as a functional of the one-particle density as in the Hohenberg-Kohn-Sham theory, we use a conventional ...
Approximate relativistic corrections to atomic radial wave functions*
The mass-velocity and Darwin terms of the one-electron-atom Pauli equation have been added to the Hartree-Fock differential equations by using the HX formula to calculate a loca...
<i>A</i> <i>b</i> <i>i</i> <i>n</i> <i>i</i> <i>t</i> <i>i</i> <i>o</i> effective core potentials including relativistic effects. V. SCF calculations with ω–ω coupling including results for Au2+, TlH, PbS, and PbSe
A b initio self-consistent field calculations are reported for a series of diatomic molecules using relativistic effective core potentials (REP) and basis sets appropriate for ω...
Publication Info
- Year
- 1978
- Type
- article
- Volume
- 18
- Issue
- 6
- Pages
- 2701-2711
- Citations
- 314
- Access
- Closed
External Links
Social Impact
Altmetric
PlumX Metrics
Social media, news, blog, policy document mentions
Citation Metrics
314
OpenAlex
Cite This
J. H. Wood,
A. M. Boring
(1978).
Improved Pauli Hamiltonian for local-potential problems.
Physical review. B, Condensed matter
, 18
(6)
, 2701-2711.
https://doi.org/10.1103/physrevb.18.2701
Identifiers
- DOI
- 10.1103/physrevb.18.2701