Skip to main content
OSTI.GOVU.S. Department of Energy Office of Scientific and Technical Information
U.S. Department of Energy
Office of Scientific and Technical Information
 

Matrix Methods for Solving Hartree-Fock Equations in Atomic Structure Calculations and Line Broadening

Journal Article · · Atoms
DOI:https://doi.org/10.3390/atoms6020022· OSTI ID:2496816
; ; ; ; ; ;

Atomic structure of N-electron atoms is often determined by solving the Hartree-Fock equations, which are a set of integro-differential equations. The integral part of the Hartree-Fock equations treats electron exchange, but the Hartree-Fock equations are not often treated as an integro-differential equation. The exchange term is often approximated as an inhomogeneous or an effective potential so that the Hartree-Fock equations become a set of ordinary differential equations (which can be solved using the usual shooting methods). Because the Hartree-Fock equations are an iterative-refinement method, the inhomogeneous term relies on the previous guess of the wavefunction. In addition, there are numerical complications associated with solving inhomogeneous differential equations. This work uses matrix methods to solve the Hartree-Fock equations as an integro-differential equation. It is well known that a derivative operator can be expressed as a matrix made of finite-difference coefficients; energy eigenvalues and eigenvectors can be obtained by using linear-algebra packages. The integral (exchange) part of the Hartree-Fock equation can be approximated as a sum and written as a matrix. The Hartree-Fock equations can be solved as a matrix that is the sum of the differential and integral matrices. We compare calculations using this method against experiment and standard atomic structure calculations. This matrix method can also be used to solve for free-electron wavefunctions, thus improving how the atoms and free electrons interact. This technique is important for spectral line broadening in two ways: it improves the atomic structure calculations, and it improves the motion of the plasma electrons that collide with the atom.

Sponsoring Organization:
USDOE
Grant/Contract Number:
SC0010623
OSTI ID:
2496816
Alternate ID(s):
OSTI ID: 1511657
OSTI ID: 1457406
OSTI ID: 1483531
Journal Information:
Atoms, Journal Name: Atoms Journal Issue: 2 Vol. 6; ISSN 2218-2004; ISSN ATOMC5
Publisher:
MDPI AGCopyright Statement
Country of Publication:
Switzerland
Language:
English

References (38)

Relativistic Quantum Theory of Atoms and Molecules book January 2007
Quantum Mechanics of One- and Two-Electron Atoms book January 1957
N�herungsmethode zur L�sung des quantenmechanischen Mehrk�rperproblems journal January 1930
A comparison of a second-order quantum mechanical and an all-order semi-classical electron broadening model journal October 2001
Electron-impact broadening of the 3s–3p lines in low-Z Li-like ions journal September 2003
Electron collisional broadening of isolated lines from multiply-ionized atoms journal April 2000
Model uncertainties of local-thermodynamic-equilibrium K-shell spectroscopy journal September 2016
The Wave Mechanics of an Atom with a Non-Coulomb Central Field. Part I. Theory and Methods journal January 1928
A spectroscopic determination of the mass distribution of DA white dwarfs journal July 1992
LABORATORY MEASUREMENTS OF WHITE DWARF PHOTOSPHERIC SPECTRAL LINES: H β journal June 2015
On the Hartree-Fock equations for helium with non-orthogonal orbitals journal November 1968
Electron scattering by atomic hydrogen: the distorted-wave second Born approximation journal December 1980
Atomic data for opacity calculations. XIII. Line profiles for transitions in hydrogenic ions journal October 1990
Exact second-order distorted-wave calculation for hydrogen including second-order exchange journal September 1991
The Los Alamos suite of relativistic atomic physics codes journal May 2015
Opacities for stellar envelopes journal February 1994
General Impact Theory of Pressure Broadening journal November 1958
Pressure Broadening as a Prototype of Relaxation journal July 1963
Self-Consistent Equations Including Exchange and Correlation Effects journal November 1965
A Simplification of the Hartree-Fock Method journal February 1951
Optimized effective atomic central potential journal July 1976
Full Coulomb calculation of Stark broadening in laser-produced plasmas journal July 1984
Stark broadening of spectral lines along the isoelectronic sequence of Li journal June 1992
Convergent close-coupling method for the calculation of electron scattering on hydrogenlike targets journal February 1994
Stark broadening of resonance transitions in B III journal April 1996
Grid-based numerical Hartree-Fock solutions of polyatomic molecules journal October 2007
Effect of higher-order multipole moments on the Stark line shape journal August 2016
Stark broadening of the B III 2 s − 2 p lines journal December 1997
Full Coulomb calculation of Stark broadened spectra from multielectron ions: A focus on the dense plasma line shift journal October 2000
Standard line broadening impact theory for hydrogen including penetrating collisions journal October 2005
Electron Impact Excitation of Atoms journal April 1968
Real-space mesh techniques in density-functional theory journal October 2000
Computer Solutions to the Schrödinger Equation journal May 1972
Matrix Numerov method for solving Schrödinger’s equation journal November 2012
LAPACK Users' Guide software January 1999
Energy levels for the stable isotopes of atomic helium( 4 He I and 3 He I) journal February 2006
The Theory of Atomic Structure and Spectra book December 1981
The Second Workshop on Lineshape Code Comparison: Isolated Lines journal May 2014

Similar Records

Numerical solution of the Hartree-Fock equation in molecular geometries
Journal Article · Sun Nov 14 23:00:00 EST 2010 · Physical Review. A · OSTI ID:21528639

Related Subjects