Effect of soften on colossal manganites

Lu, Wei-Chun

31 July 2002

Abstract The softening effects of ferromagnetic magnon on some ferromagnetic semiconductors and colossal magnetoresistance manganites have attracted much attention. Such effect can be calculated from the single orbital ferromagnetic Kondo lattice model in proper conducting carrier numbers utilizing the equation of motion method with one magnon excitation and Random Phase approximations. However, if we take into account the Coulomb repulsion and use the Gutzwiller projection method to transfer this repulsion force to conducting bandwidth modulation, the softening effect disappear. This paper describes qualitively the effect of softening on properties of different colossal manganites.

spin wave

double exchange model

kondo lattice model

Density-Matrix Renormalization-Group Analysis of Kondo and XY models

Juozapavicius, Ausrius

January 2001

No description available.

Quantum spin chain

DMRG

XY model

Ising model

Kondo lattice model

magnetization

Density-Matrix Renormalization-Group Analysis of Kondo and XY models

Juozapavicius, Ausrius

January 2001

No description available.

Quantum spin chain

DMRG

XY model

Ising model

Kondo lattice model

magnetization

Temperaturabhängige elektronische Struktur und Magnetismus von metallischen Systemen mit lokalisierten Momenten / Anwendung auf Gadolinium

Santos, Carlos Augusto Machamba dos

01 June 2006

No description available.

Magnetismus

Kondo-Gitter-Modell

Gadolinium

Bandstrukturrechnungen

Magnetism

Gadolinium

Kondo-lattice model

Bandstructure Calculations

530 Physik

29 Physik, Astronomie

ddc:530

Unconventional Phases in Two-Dimensional Hubbard and Kondo-Lattice Models by Variational Cluster Approaches

Lenz, Benjamin

16 December 2016

No description available.

530

Physik (PPN621336750)

Quantum Cluster Techniques

Dimensional Crossover

Variational Cluster Approximation

Heavy Fermions

Kondo Lattice Model

Superconductivity

Mott Transition

Hubbard Model

Antiferromagnetism

Flussgleichungen zur Beschreibung statischer und dynamischer Eigenschaften des eindimensionalen Kondo-Gitter-Modells

Sommer, Torsten

24 February 2005

In dieser Arbeit wird das eindimensionale Kondo-Gitter-Modell untersucht, das die Wechselwirkung eines Gitters lokaler magnetischer Momente mit unkorrelierten Leitungselektronen beschreibt. Mit Hilfe der Methode der kontinuierlichen unitären Transformationen (Flussgleichungen) wird das Modell im Parameterbereich schwacher Wechselwirkungsstärke betrachtet. In diesem Bereich zeigt das Modell so genanntes Luttinger-Flüssigkeitsverhalten. Im Rahmen der Flussgleichungsmethode wird der Hamilton-Operator auf ein effektives Modell abgebildet, in dem Elektronen und Spinmomente vollständig entkoppelt sind. Das Resultat dieses Prozesses ist ein Modell, das ein nichtwechselwirkendes Elektronengas und eine Heisenberg-Spinkette beschreibt. Das Eigenwertproblem der Heisenberg-Kette wird im Rahmen einer Schwinger-Boson-Molekularfeld-Theorie beschrieben. Zur Charakterisierung der Grundzustandseigenschaften des eindimensionalen Kondo-Gitter-Modells wurden verschiedene Erwartungswerte und Korrelationsfunktionen betrachtet. Neben statischen Größen, wie der Ladungskorrelationsfunktion der Elektronen oder der Spinkorrelationsfunktion der lokalen Spinmomente, werden dynamische Größen, wie die elektronische Zustandsdichte oder die dynamischen Spinstrukturfaktoren der Elektronen und der lokalen Spinmomente, berechnet. / The one-dimensional Kondo lattice model is investigated. This model describes the interaction between a lattice of local magnetic moments and uncorrelated conduction electrons. It is studied by means of the continuous unitary transformation's method (flow equations) within the parameter regime of weak interaction strength. Here the model shows so called Luttinger liquid behaviour. Within the framework of the flow equation's method the original Hamiltonian is mapped on an effective model, where electrons and local moments are completely decoupled. The result of this process is a model describing a non-interacting electron gas and a Heisenberg spin chain. The eigenvalue problem of the Heisenberg chain is described within a Schwinger bosons molecular field theory. In order to characterise the ground state properties of the one-dimensional Kondo lattice model different expectation values and correlation functions are investigated. Beside static properties like the charge correlation function of the electrons or the local moment's spin correlation function, dynamic properties are determined, like the electronic density of states or the dynamic spin structure factor of both the electrons and the local moments.

Flussgleichungen

Kondo-Gitter-Modell

Luttinger-Flüssigkeiten

Flow equations

Kondo lattice model

Luttinger liquids

ddc:530

rvk:UP 4000

Fluss

Kondo-Modell

Unitäre Transformation

Efeito Kondo e magnetismo em uma rede Kagome

Silva Junior, José Luiz Ferreira da

January 2012

Neste trabalho estudamos o modelo da rede de Kondo em uma rede kagome, buscando uma maior compreensão dos efeitos da frustração geométrica em sistemas de férmions pesados. Para tanto, fizemos uma aproximação de campo médio no hamiltoniano do sistema que serve para todas as fases do sistema. Analisamos inicialmente o caso não magnético. Obtemos neste limite as energias eletrônicas e as funções de Green necessárias ao cálculo numérico autoconsistente das ocupações e do parâmetro de Kondo. Os resultados encontrados estão em concordância qualitativa com trabalhos publicados em outras geometrias. A seguir analisamos o caso magnético, onde introduzimos uma aproximação suplementar, a qual é compatível com a de campo médio já considerada e, em princípio, existente apenas em sistemas com frustração geométrica. Realizamos cálculos autoconsistentes através de somas sobre as frequências de Matsubara. Os resultados mostram que não há coexistência entre ordem magnética e efeito Kondo, além de haver a supressão do antiferromagnetismo com o aumento de temperatura e variações no preenchimento de bandas. / In this work we study the Kondo Lattice model for the kagome lattice, in order to understand better the effects of geometrical frustration in heavy-fermion systems. In this context, we consider a mean field scheme valid for all the system’s phases. Firstly, we analyzed the nonmagnetic case. In this approximation the electron energies and spectral functions are reachable, then we use the density of states to calculate the occupations selfconsistently. Our results are qualitatively compared with previous works in other geometries. In the second part we introduce an approximation for magnestism, which takes into account the mean field scheme considered and the presence of geometrical frustration. Self-consistent calculations are done through the frequencies summation method. Our results show that the magnetism is supressed when the temperature is increased or the band filling deviates from half-filling. Besides, the coexistence of magnetic order and Kondo effect is not observable.

Física da matéria condensada

Efeito kondo

Sistemas de férmions pesados

Funcoes de green

Sistemas hamiltonianos

Geometrical frustration

Kondo lattice model

Heavy fermions

Kagome lattice

Efeito Kondo e magnetismo em uma rede Kagome

Silva Junior, José Luiz Ferreira da

January 2012

Neste trabalho estudamos o modelo da rede de Kondo em uma rede kagome, buscando uma maior compreensão dos efeitos da frustração geométrica em sistemas de férmions pesados. Para tanto, fizemos uma aproximação de campo médio no hamiltoniano do sistema que serve para todas as fases do sistema. Analisamos inicialmente o caso não magnético. Obtemos neste limite as energias eletrônicas e as funções de Green necessárias ao cálculo numérico autoconsistente das ocupações e do parâmetro de Kondo. Os resultados encontrados estão em concordância qualitativa com trabalhos publicados em outras geometrias. A seguir analisamos o caso magnético, onde introduzimos uma aproximação suplementar, a qual é compatível com a de campo médio já considerada e, em princípio, existente apenas em sistemas com frustração geométrica. Realizamos cálculos autoconsistentes através de somas sobre as frequências de Matsubara. Os resultados mostram que não há coexistência entre ordem magnética e efeito Kondo, além de haver a supressão do antiferromagnetismo com o aumento de temperatura e variações no preenchimento de bandas. / In this work we study the Kondo Lattice model for the kagome lattice, in order to understand better the effects of geometrical frustration in heavy-fermion systems. In this context, we consider a mean field scheme valid for all the system’s phases. Firstly, we analyzed the nonmagnetic case. In this approximation the electron energies and spectral functions are reachable, then we use the density of states to calculate the occupations selfconsistently. Our results are qualitatively compared with previous works in other geometries. In the second part we introduce an approximation for magnestism, which takes into account the mean field scheme considered and the presence of geometrical frustration. Self-consistent calculations are done through the frequencies summation method. Our results show that the magnetism is supressed when the temperature is increased or the band filling deviates from half-filling. Besides, the coexistence of magnetic order and Kondo effect is not observable.

Física da matéria condensada

Efeito kondo

Sistemas de férmions pesados

Funcoes de green

Sistemas hamiltonianos

Geometrical frustration

Kondo lattice model

Heavy fermions

Kagome lattice

Efeito Kondo e magnetismo em uma rede Kagome

Silva Junior, José Luiz Ferreira da

January 2012

Neste trabalho estudamos o modelo da rede de Kondo em uma rede kagome, buscando uma maior compreensão dos efeitos da frustração geométrica em sistemas de férmions pesados. Para tanto, fizemos uma aproximação de campo médio no hamiltoniano do sistema que serve para todas as fases do sistema. Analisamos inicialmente o caso não magnético. Obtemos neste limite as energias eletrônicas e as funções de Green necessárias ao cálculo numérico autoconsistente das ocupações e do parâmetro de Kondo. Os resultados encontrados estão em concordância qualitativa com trabalhos publicados em outras geometrias. A seguir analisamos o caso magnético, onde introduzimos uma aproximação suplementar, a qual é compatível com a de campo médio já considerada e, em princípio, existente apenas em sistemas com frustração geométrica. Realizamos cálculos autoconsistentes através de somas sobre as frequências de Matsubara. Os resultados mostram que não há coexistência entre ordem magnética e efeito Kondo, além de haver a supressão do antiferromagnetismo com o aumento de temperatura e variações no preenchimento de bandas. / In this work we study the Kondo Lattice model for the kagome lattice, in order to understand better the effects of geometrical frustration in heavy-fermion systems. In this context, we consider a mean field scheme valid for all the system’s phases. Firstly, we analyzed the nonmagnetic case. In this approximation the electron energies and spectral functions are reachable, then we use the density of states to calculate the occupations selfconsistently. Our results are qualitatively compared with previous works in other geometries. In the second part we introduce an approximation for magnestism, which takes into account the mean field scheme considered and the presence of geometrical frustration. Self-consistent calculations are done through the frequencies summation method. Our results show that the magnetism is supressed when the temperature is increased or the band filling deviates from half-filling. Besides, the coexistence of magnetic order and Kondo effect is not observable.

Física da matéria condensada

Efeito kondo

Sistemas de férmions pesados

Funcoes de green

Sistemas hamiltonianos

Geometrical frustration

Kondo lattice model

Heavy fermions

Kagome lattice

Flussgleichungen zur Beschreibung statischer und dynamischer Eigenschaften des eindimensionalen Kondo-Gitter-Modells

Sommer, Torsten

15 March 2005

In dieser Arbeit wird das eindimensionale Kondo-Gitter-Modell untersucht, das die Wechselwirkung eines Gitters lokaler magnetischer Momente mit unkorrelierten Leitungselektronen beschreibt. Mit Hilfe der Methode der kontinuierlichen unitären Transformationen (Flussgleichungen) wird das Modell im Parameterbereich schwacher Wechselwirkungsstärke betrachtet. In diesem Bereich zeigt das Modell so genanntes Luttinger-Flüssigkeitsverhalten. Im Rahmen der Flussgleichungsmethode wird der Hamilton-Operator auf ein effektives Modell abgebildet, in dem Elektronen und Spinmomente vollständig entkoppelt sind. Das Resultat dieses Prozesses ist ein Modell, das ein nichtwechselwirkendes Elektronengas und eine Heisenberg-Spinkette beschreibt. Das Eigenwertproblem der Heisenberg-Kette wird im Rahmen einer Schwinger-Boson-Molekularfeld-Theorie beschrieben. Zur Charakterisierung der Grundzustandseigenschaften des eindimensionalen Kondo-Gitter-Modells wurden verschiedene Erwartungswerte und Korrelationsfunktionen betrachtet. Neben statischen Größen, wie der Ladungskorrelationsfunktion der Elektronen oder der Spinkorrelationsfunktion der lokalen Spinmomente, werden dynamische Größen, wie die elektronische Zustandsdichte oder die dynamischen Spinstrukturfaktoren der Elektronen und der lokalen Spinmomente, berechnet. / The one-dimensional Kondo lattice model is investigated. This model describes the interaction between a lattice of local magnetic moments and uncorrelated conduction electrons. It is studied by means of the continuous unitary transformation's method (flow equations) within the parameter regime of weak interaction strength. Here the model shows so called Luttinger liquid behaviour. Within the framework of the flow equation's method the original Hamiltonian is mapped on an effective model, where electrons and local moments are completely decoupled. The result of this process is a model describing a non-interacting electron gas and a Heisenberg spin chain. The eigenvalue problem of the Heisenberg chain is described within a Schwinger bosons molecular field theory. In order to characterise the ground state properties of the one-dimensional Kondo lattice model different expectation values and correlation functions are investigated. Beside static properties like the charge correlation function of the electrons or the local moment's spin correlation function, dynamic properties are determined, like the electronic density of states or the dynamic spin structure factor of both the electrons and the local moments.

info:eu-repo/classification/ddc/530

ddc:530