Real-Space Approach to Time Dependent Current Density Functional Theory

Jensen, Daniel S.

09 July 2010

A real-space time-domain calculation of the frequency-dependent dielectric constant of nonmetallic crystals is outlined and the integrals required for this calculation are computed. The outline is based on time dependent current density functional theory and is partially implemented in the ab initio density functional theory FIREBALL program. The addition of a vector potential to the Hamiltonian of the system is discussed as well as the need to include the current density in addition to the particle density. The derivation of gradient integrals within a localized atomic-like orbital basis is presented for use in constructing the current density. Due to the generality of the derivation we also give the derivation of the kinetic energy, dipole, and overlap interactions.

density functional theory

molecular integrals

Astrophysics and Astronomy

Physics

Magnetismo orbital em sistemas de muitos elétrons / Orbital magnetism in many electrons systems

Morbec, Juliana Maria Abreu da Silva

06 March 2009

Neste trabalho investigamos os efeitos do magnetismo orbital sobre o gás de elétrons tridimensional e sobre íons de camadas abertas em matrizes metálicas. Derivamos uma expressão analítica fechada para a energia de troca do gás de elétrons tridimensional na presença de fortes campos magnéticos, incluindo contribuições do segundo nível de Landau e polarização de spin arbitrária. Esse cálculo generaliza e corrige resultados anteriores disponíveis na literatura. Em seguida, realizamos um cálculo numérico da energia de troca do gás de elétrons tridimensional na presença de campos magnéticos, permitindo a ocupação de um número ilimitado de níveis de Landau, possibilitando assim a obtenção da energia de troca para quaisquer valores de campo magnético e densidade. Em uma abordagem independente, usamos as aproximações de Thomas-Fermi e Thomas-Fermi-Dirac para construir modelos simples para a função dielétrica do gás de elétrons tridimensional no regime de campos magnéticos muito fortes (apenas o primeiro nível de Landau ocupado). Finalmente, estabelecemos vínculos entre os tratamentos fenomenológicos e de primeiros princípios do magnetismo orbital em íons de camadas abertas em matrizes metálicas. Esses vínculos forneceram um embasamento teórico para o uso dos termos de polarização orbital em cálculos Kohn-Sham e levaram à obtenção de expressões aproximadas para os funcionais de troca-correlação da teoria do funcional da densidade de corrente. / In this work, we investigate the effects of orbital magnetism in the three-dimensional electron gas and in open-shell ions in a solid. We derive a closed analytical expression for the exchange energy of the three-dimensional electron gas in strong magnetic fields including the contribution of the second Landau level and arbitrary spin polarization. This calculation generalizes and corrects earlier results available in the literature. Next, we perform a numerical calculation of the exchange energy of the three-dimensional electron gas in a magnetic field, allowing several Landau levels to be occupied, to obtain the exchange energy for arbitrary values of magnetic field and density. In an independent approach, we use the Thomas-Fermi and Thomas-Fermi-Dirac approximations to construct simple model dielectric functions for the three-dimensional electron gas in the strong magnetic field regime (where only the lowest Landau level is occupied). Finally, we establish links between the phenomenological and the first-principles treatment of orbital magnetism in open-shell ions in solids. These links provide a theoretical foundation for the use of orbital polarization terms in Kohn-Sham calculations and allow to obtain approximations to the exchange-correlation functionals of current-density functional theory.

campos magnéticos ultrafortes

current-density functional theory

energia de troca

exchange energy

magnetismo orbital

orbital magnetism

orbital polarization terms

strong magnetic fields

termos de polarização orbital

Magnetismo orbital em sistemas de muitos elétrons / Orbital magnetism in many electrons systems

Juliana Maria Abreu da Silva Morbec

06 March 2009

Neste trabalho investigamos os efeitos do magnetismo orbital sobre o gás de elétrons tridimensional e sobre íons de camadas abertas em matrizes metálicas. Derivamos uma expressão analítica fechada para a energia de troca do gás de elétrons tridimensional na presença de fortes campos magnéticos, incluindo contribuições do segundo nível de Landau e polarização de spin arbitrária. Esse cálculo generaliza e corrige resultados anteriores disponíveis na literatura. Em seguida, realizamos um cálculo numérico da energia de troca do gás de elétrons tridimensional na presença de campos magnéticos, permitindo a ocupação de um número ilimitado de níveis de Landau, possibilitando assim a obtenção da energia de troca para quaisquer valores de campo magnético e densidade. Em uma abordagem independente, usamos as aproximações de Thomas-Fermi e Thomas-Fermi-Dirac para construir modelos simples para a função dielétrica do gás de elétrons tridimensional no regime de campos magnéticos muito fortes (apenas o primeiro nível de Landau ocupado). Finalmente, estabelecemos vínculos entre os tratamentos fenomenológicos e de primeiros princípios do magnetismo orbital em íons de camadas abertas em matrizes metálicas. Esses vínculos forneceram um embasamento teórico para o uso dos termos de polarização orbital em cálculos Kohn-Sham e levaram à obtenção de expressões aproximadas para os funcionais de troca-correlação da teoria do funcional da densidade de corrente. / In this work, we investigate the effects of orbital magnetism in the three-dimensional electron gas and in open-shell ions in a solid. We derive a closed analytical expression for the exchange energy of the three-dimensional electron gas in strong magnetic fields including the contribution of the second Landau level and arbitrary spin polarization. This calculation generalizes and corrects earlier results available in the literature. Next, we perform a numerical calculation of the exchange energy of the three-dimensional electron gas in a magnetic field, allowing several Landau levels to be occupied, to obtain the exchange energy for arbitrary values of magnetic field and density. In an independent approach, we use the Thomas-Fermi and Thomas-Fermi-Dirac approximations to construct simple model dielectric functions for the three-dimensional electron gas in the strong magnetic field regime (where only the lowest Landau level is occupied). Finally, we establish links between the phenomenological and the first-principles treatment of orbital magnetism in open-shell ions in solids. These links provide a theoretical foundation for the use of orbital polarization terms in Kohn-Sham calculations and allow to obtain approximations to the exchange-correlation functionals of current-density functional theory.

campos magnéticos ultrafortes

energia de troca

magnetismo orbital

termos de polarização orbital

current-density functional theory

exchange energy

orbital magnetism

orbital polarization terms

strong magnetic fields

Foundation of Density Functionals in the Presence of Magnetic Field

Laestadius, Andre

January 2014

This thesis contains four articles related to mathematical aspects of Density Functional Theory. In Paper A, the theoretical justification of density methods formulated with current densities is addressed. It is shown that the set of ground-states is determined by the ensemble-representable particle and paramagnetic current density. Furthermore, it is demonstrated that the Schrödinger equation with a magnetic field is not uniquely determined by its ground-state solution. Thus, a wavefunction may be the ground-state of two different Hamiltonians, where the Hamiltonians differ by more than a gauge transformation. This implies that the particle and paramagnetic current density do not determine the potentials of the system and, consequently, no Hohenberg-Kohn theorem exists for Current Density Functional Theory formulated with the paramagnetic current density. On the other hand, by instead using the particle density as data, we show that the scalar potential in the system's Hamiltonian is determined for a fixed magnetic field. This means that the Hohenberg-Kohn theorem continues to hold in the presence of a magnetic field, if the magnetic field has been fixed. Paper B deals with N-representable density functionals that also depend on the paramagnetic current density. Here the Levy-Lieb density functional is generalized to include the paramagnetic current density. It is shown that a wavefunction exists that minimizes the "free" Hamiltonian subject to the constraints that the particle and paramagnetic current density are held fixed. Furthermore, a convex and universal current density functional is introduced and shown to equal the convex envelope of the generalized Levy-Lieb density functional. Since this functional is convex, the problem of finding the particle and paramagnetic current density that minimize the energy is related to a set of Euler-Lagrange equations. In Paper C, an N-representable Kohn-Sham approach is developed that also include the paramagnetic current density. It is demonstrated that a wavefunction exists that minimizes the kinetic energy subject to the constraint that only determinant wavefunctions are considered, as well as that the particle and paramagnetic current density are held fixed. Using this result, it is then shown that the ground-state energy can be obtained by minimizing an energy functional over all determinant wavefunctions that have finite kinetic energy. Moreover, the minimum is achieved and this determinant wavefunction gives the ground-state particle and paramagnetic current density. Lastly, Paper D addresses the issue of a Hohenberg-Kohn variational principle for Current Density Functional Theory formulated with the total current density. Under the assumption that a Hohenberg-Kohn theorem exists formulated with the total current density, it is shown that the map from particle and total current density to the vector potential enters explicitly in the energy functional to be minimized. Thus, no variational principle as that of Hohenberg and Kohn exists for density methods formulated with the total current density. / <p>QC 20140523</p>

Current density functional theory

Hohenberg-Kohn theorems

paramagnetic current density functionals

Kohn-Sham theory

Levy-Lieb functional

variational principle

N-representable

degeneracy