Interplay of magnetic, orthorhombic, and superconducting phase transitions in iron-based superconductors

Schmiedt, Jacob

29 October 2014

The physics of iron pnictides has been the subject of intense research for half a decade since the discovery of superconductivity in doped LaFeAsO in 2008. By now there exists a large number of different materials that are summarized under the term "pnictides'' with significant differences in their crystal structure, electronic properties, and their phase diagrams. This thesis is concerned with the investigation of the various phase transitions that are observed in the underdoped compounds of the pnictide subgroups RFeAsO, where R is a rare-earth element, and AFe_2As_2, where A is an alkaline-earth element. These compounds display two closely bound transitions from a tetragonal to an orthorhombic phase and from a paramagnetic to an antiferromagnetic metal. Both symmetry-broken phases are suppressed by doping or pressure and close to their disappearance superconductivity sets in. The superconducting state is stabilized until some optimal doping or pressure is reached and gets suppressed thereafter. The central goal of this thesis is to improve our understanding of the interplay between these three phases and to describe the various phase transitions. We start from an itinerant picture that explains the magnetism as a result of an excitonic instability and show how the other phases can be included into this picture. This approach is based on the the observation that the compounds we are interested in have a Fermi surface with multiple nested electron and hole pockets and that they have small to intermediate interaction strengths. The thesis starts with a study of the doping dependence of the antiferromagnetic phase transition in four different five-orbital models. We use the random-phase approximation to determine the transition temperature, the dominant ordering vector, and the contribution of the different orbitals to the ordering. This allows us to identify the more realistic models, which give results that are in good agreement with experimental observations. In addition to the frequently made assumption of orbital-independent interaction potentials we study the effect of a reduction of the interaction strengths that involve the d_{xy} orbital. We find that this tunes the system between two different nesting instabilities. A reduction of the interactions that involve the d_{xy} orbital also enhances the tendency towards incommensurate (IC) order. For a weak reduction this tendency is compensated by the presence of the orthorhombic phase. However, for a reduction of 30%, as it is suggested by constrained random-phase-approximation calculations, we always find large doping ranges, where a state with IC order has the highest transition temperature. We continue the investigation of the magnetic phase transition by studying the competition of different possible types of antiferromagnetic order that arises from the presence of two degenerate nesting instabilities with the ordering vectors (pi,0) and (0,pi). We derive a Ginzburg-Landau free energy from a microscopic two-band model and find that the presence of the experimentally observed stripe phase strongly depends on the number and size of the hole pockets in the system and on the doping. We show that within the picture of a purely magnetically driven nematic phase transition, which breaks the C_4 symmetry and induces the orthorhombic distortion, the nematic phase displays exactly the same dependence on the model parameters as the magnetic stripe phase. We propose that in addition to the purely magnetically driven nematic instability there is a ferro-orbital instability in the system that stabilizes the nematic transition and, thus, explains the experimentally observed robustness of the orthorhombic transition. We argue that including a ferro-orbital instability into the picture may also be necessary to reproduce the transition from simultaneous first-order transitions into an orthorhombic antiferromagnetic state to two separate second-order transitions, which is observed as a function of doping. Finally, a study of the superconducting phase transition inside the antiferromagnetic phase that is observed in some pnictide compounds is presented. We present an approach to calculate the fluctuation-mediated pairing interaction in the spin-density-wave phase of a multiband system, which is based on the random-phase approximation. This approach is applied to a minimal two-band model for the pnictides to study the effect of the various symmetry-allowed bare on-site interactions on the gap symmetry and structure. We find a competition between various even- and odd-parity states and over a limited parameter range a p_x-wave state is the dominant instability. The largest part of the parameter space is dominated by even parity states but the gap structure sensitively depends on the bare interactions. We propose that the experimentally observed transition from a nodeless to a nodal gap can be due to changes in the on-site interaction potentials.

eisenbasierte Supraleiter

Pniktide

Spin-Dichte-Welle

Phasenübergänge

nematische Phase

Supraleitung

Koexistenz

Magnetismus

Antiferromagnetismus

Festkörpertheorie

Vielteilchentheorie

iron-based superconductors

pnictides

spin-density wave

phase transitions

nematic phase

superconductivity

coexistence

magnetism

antiferromagnetism

condensed-matter theory

many-body theory

ddc:530

rvk:UP 2200

Electronic self-organization in layered transition metal dichalcogenides

Ritschel, Tobias

30 October 2015

The interplay between different self-organized electronically ordered states and their relation to unconventional electronic properties like superconductivity constitutes one of the most exciting challenges of modern condensed matter physics. In the present thesis this issue is thoroughly investigated for the prototypical layered material 1T-TaS2 both experimentally and theoretically. At first the static charge density wave order in 1T-TaS2 is investigated as a function of pressure and temperature by means of X-ray diffraction. These data indeed reveal that the superconductivity in this material coexists with an inhomogeneous charge density wave on a macroscopic scale in real space. This result is fundamentally different from a previously proposed separation of superconducting and insulating regions in real space. Furthermore, the X-ray diffraction data uncover the important role of interlayer correlations in 1T-TaS2. Based on the detailed insights into the charge density wave structure obtained by the X-ray diffraction experiments, density functional theory models are deduced in order to describe the electronic structure of 1T-TaS2 in the second part of this thesis. As opposed to most previous studies, these calculations take the three-dimensional character of the charge density wave into account. Indeed the electronic structure calculations uncover complex orbital textures, which are interwoven with the charge density wave order and cause dramatic differences in the electronic structure depending on the alignment of the orbitals between neighboring layers. Furthermore, it is demonstrated that these orbital-mediated effects provide a route to drive semiconductor-to-metal transitions with technologically pertinent gaps and on ultrafast timescales. These results are particularly relevant for the ongoing development of novel, miniaturized and ultrafast devices based on layered transition metal dichalcogenides. The discovery of orbital textures also helps to explain a number of long-standing puzzles concerning the electronic self-organization in 1T-TaS2 : the ultrafast response to optical excitations, the high sensitivity to pressure as well as a mysterious commensurate phase that is commonly thought to be a special phase a so-called “Mott phase” and that is not found in any other isostructural modification.

info:eu-repo/classification/ddc/530

ddc:530

Phases, Transitions, Patterns, And Excitations In Generalized Bose-Hubbard Models

Kurdestany, Jamshid Moradi

05 1900

This thesis covers most of my work in the field of ultracold atoms loaded in optical lattices. This thesis can be divided into five different parts. In Chapter 1, after a brief introduction to the field of optical lattices I review the fundamental aspects pertaining to the physics of systems in periodic potentials and a short overview of the experiments on ultracold atoms in an optical lattice. In Chapter 2 we develop an inhomogeneous mean-field theory for the extended Bose-Hubbard model with a quadratic, confining potential. In the absence of this poten¬tial, our mean-field theory yields the phase diagram of the homogeneous extended Bose-Hubbard model. This phase diagram shows a superfluid (SF) phase and lobes of Mott-insulator(MI), density-wave(DW), and supersolid (SS) phases in the plane of the chemical potential and on-site repulsion ; we present phase diagrams for representative values of , the repulsive energy for bosons on nearest-neighbor sites. We demonstrate that, when the confining potential is present, superfluid and density-wave order parameters are nonuniform; in particular, we obtain, for a few representative values of parameters, spherical shells of SF, MI ,DW ,and SSphases. We explore the implications of our study for experiments on cold-atom dipolar con¬densates in optical lattices in a confining potential. In Chapter3 we present an extensive study of Mottinsulator( MI) and superfluid (SF) shells in Bose-Hubbard (BH) models for bosons in optical lattices with har¬monic traps. For this we develop an inhomogeneous mean-field theory. Our results for the BH model with one type of spinless bosons agrees quantitatively with quan¬tum Monte Carlo(QMC) simulations. Our approach is numerically less intensive than such simulations, so we are able to perform calculations on experimentally realistic, large three-dimensional(3D) systems, explore a wide range of parameter values, and make direct contact with a variety of experimental measurements. We also generalize our inhomogeneous mean-field theory to study BH models with har¬monic traps and(a) two species of bosons or(b) spin-1bosons. With two species of bosons we obtain rich phase diagrams with a variety of SF and MI phases and as¬sociated shells, when we include a quadratic confining potential. For the spin-1BH model we show, in a representative case, that the system can display alternating shells of polar SF and MI phases; and we make interesting predictions for experi¬ments in such systems. . In Chapter 4 we carry out an extensive study of the phase diagrams of the ex-tended Bose Hubbard model, with a mean filling of one boson per site, in one dimension by using the density matrix renormalization group and show that it contains Superfluid (SF), Mott-insulator (MI), density-wave (DW) and Haldane ¬insulator(HI) phases. We show that the critical exponents and central charge for the HI-DW,MI-HI and SF-MI transitions are consistent with those for models in the two-dimensional Ising, Gaussian, and Berezinskii-Kosterlitz-Thouless (BKT) uni¬versality classes, respectively; and we suggest that the SF-HI transition may be more exotic than a simple BKT transition. We show explicitly that different bound¬ary conditions lead to different phase diagrams.. In Chapter 5 we obtain the excitation spectra of the following three generalized of Bose-Hubbard(BH) models:(1) a two-species generalization of the spinless BH model, (2) a single-species, spin-1 BH model, and (3) the extended Bose-Hubbard model (EBH) for spinless interacting bosons of one species. In all the phases of these models we show how to obtain excitation spectra by using the random phase approximation (RPA). We compare the results of our work with earlier studies of related models and discuss implications for experiments.

Ultracold Atoms

Optical Lattices

Superfluid Phases

Bose-Hubbard Model

Mean-Field Theory

Supersolid Phases

Mott-Insulator Phases

Bosons

Bose-Einstein Condensation

Density-Wave Phases

Phase Diagrams

Random-Phase-Approximation (RPA)

Superfluid-Haldane Insulator Transition

Quantum Phase Transition

Random Phase Approximation

Phase Transitions

Superfluid-Mott-Insulator Transition

Bose-Hubbard Models

Condensed Matter Physics

Études calorimétriques des comportements multicritiques des phases ondes de densité de spin dans un composé moléculaire

PESTY, François

14 June 1993

Mes travaux ont été consacrés à l'étude expérimentale d'un composé moléculaire de basse dimensionnalité, le (TMTSF)2ClO4. C'est un supraconducteur aux températures inférieures à 1,2 K, mais un champ magnétique induit à basse température une cascade de phases Ondes de Densité de Spin (ODSIC) quantifiées, au-dessus d'environ 3 teslas. J'ai développé plusieurs appareillages et techniques expérimentales, notamment la mesure simultanée de la chaleur spécifique et de la conductibilité thermique (en champ magnétique fixe), ou de l'effet magnétocalorique (en champ magnétique variable). Mes investigations calorimétriques ont débouché sur toute une série de découvertes surprenantes qui ont suscité nombre de travaux théoriques. -1- Dans l'état supraconducteur, à champ nul, un dépairage est induit par le désordre d'anion, très similaire à l'effet analogue induit par les impuretés magnétiques dans un supraconducteur conventionnel. -2- A bas champ (B<8T), la transition métal-ODSIC présente un caractère couplage faible. -3- Certaines transitions sont partiellement réentrantes. -4- Le saut de la chaleur spécifique à la transition ?c?est-à-dire la force du couplage !-? oscille en fonction du champ magnétique, et sa valeur présente des discontinuités aux limites entre phases ODS quantifiées. -5- A fort champ, le système entre dans un régime de couplage fort (voire très fort). -6- Le comportement semble évoluer de 3D vers 2D à la traversée de la frontière. -7- La conductivité thermique semble dominée par les vibrations de réseau, mais le comportement critique est associé à la transition électronique. -8- Près de la fin de la cascade de transitions, celles-ci deviennent exothermiques quel que soit le sens de traversée de la dernière ligne de transition, le signe d?un comportement hautement irréversible. -9- Pour un échantillon refroidi assez lentement à travers la transition de mise en ordre des anions, ces lignes de transition se séparent au cours d'un processus itératif, conduisant à l'observation d'un diagramme de phases arborescent. -10- Nous avons révélé l?existence d?un point tétracritique, qui correspond à la rencontre de quatre lignes de transition en un seul point. -11- Lorsque le désordre d'anions augmente, le comportement tétracritique évolue vers un comportement bicritique, l'arborescence des lignes de transition disparaît, et nous observons un effet de dépairage similaire à celui présenté par la phase supraconductrice du même composé, mais d'amplitude beaucoup plus forte.

[PHYS:COND] Physics/Condensed Matter

Onde de Densité de Spin

métaux synthétiques

phénomènes critiques

calorimétrie

basses températures

synthetic metals

critical phenomena

calorimetry

low temperatures

high magnetic fields

Étude des phases onde de densité de spin induites par le champ magnétique dans les conducteurs organiques quasi-unidimensionnels : rôle du désordre

TSOBNANG, François

13 December 1991

Le rôle du désordre sur les phases onde de densité de spin induites par le champ magnétique (ODSIC) a été étudié sur un monocristal de (TMTSF)2ClO4. Les propriétés à basse température de ce conducteur organique quasi-unidimensionnel dépendent de la vitesse de refroidissement au passage de la transition de mise en ordre des anions qu'il subit à 24 kelvins. Nous avons utilisé cet effet de cinétique pour contrôler le taux de désordre dans l'échantillon. Nos investigations ont été effectuées à l'aide de mesures calorimétriques: d'une part, des mesures simultanées de la chaleur spécifique et de l'effet magnétocalorique en champ variable, et d'autre part, des mesures de la chaleur spécifique en champ fixe. Nous avons mis en évidence un nouveau comportement multicritique en un point de la ligne de transition du second ordre, qui sépare la phase métallique et les sous-phases ODSIC. La criticité de ce point passe de "tétracritique" à bicritique lorsque le désordre augmente. Le point "tétracritique" peut être interprété comme le résultat de la superposition de deux sous phases-ODSIC adjacentes. Nous rapportons aussi un effet de dépairage de paires électron-trou induit par le désordre non magnétique Ce dépairage diffère du comportement universel. De plus l'écart par rapport à ce dernier dépend du champ magnétique. Enfin il n'est pas monotone en fonction du champ. Par ailleurs, les mesures que nous avons effectuées montrent que la mise en ordre des anions n'influence pas directement les réentrances partielles de l'état métallique dans les sous-phases ODSIC entre 3 et 7 teslas. Ceci permet de penser que, dans ce domaine de champs magnétiques, la bande interdite ouverte dans le spectre d'énergie du fait de la mise en ordre des anions ne serait pas directement responsable des réentrances.

[PHYS:COND] Physics/Condensed Matter

conducteurs quasi-unidimensionnels

onde de densité de spin

chaleur spécifique

effet magnétocalorique

comportement multicritique

dépairage

paramètre d'ordre

spin density wave

specific heat

magnetocaloric effect

multicritical behaviour

pair-breaking

order parameter

reentrances

Interplay of magnetic, orthorhombic, and superconducting phase transitions in iron-based superconductors

Schmiedt, Jacob

07 October 2014

The physics of iron pnictides has been the subject of intense research for half a decade since the discovery of superconductivity in doped LaFeAsO in 2008. By now there exists a large number of different materials that are summarized under the term "pnictides'' with significant differences in their crystal structure, electronic properties, and their phase diagrams. This thesis is concerned with the investigation of the various phase transitions that are observed in the underdoped compounds of the pnictide subgroups RFeAsO, where R is a rare-earth element, and AFe_2As_2, where A is an alkaline-earth element. These compounds display two closely bound transitions from a tetragonal to an orthorhombic phase and from a paramagnetic to an antiferromagnetic metal. Both symmetry-broken phases are suppressed by doping or pressure and close to their disappearance superconductivity sets in. The superconducting state is stabilized until some optimal doping or pressure is reached and gets suppressed thereafter. The central goal of this thesis is to improve our understanding of the interplay between these three phases and to describe the various phase transitions. We start from an itinerant picture that explains the magnetism as a result of an excitonic instability and show how the other phases can be included into this picture. This approach is based on the the observation that the compounds we are interested in have a Fermi surface with multiple nested electron and hole pockets and that they have small to intermediate interaction strengths. The thesis starts with a study of the doping dependence of the antiferromagnetic phase transition in four different five-orbital models. We use the random-phase approximation to determine the transition temperature, the dominant ordering vector, and the contribution of the different orbitals to the ordering. This allows us to identify the more realistic models, which give results that are in good agreement with experimental observations. In addition to the frequently made assumption of orbital-independent interaction potentials we study the effect of a reduction of the interaction strengths that involve the d_{xy} orbital. We find that this tunes the system between two different nesting instabilities. A reduction of the interactions that involve the d_{xy} orbital also enhances the tendency towards incommensurate (IC) order. For a weak reduction this tendency is compensated by the presence of the orthorhombic phase. However, for a reduction of 30%, as it is suggested by constrained random-phase-approximation calculations, we always find large doping ranges, where a state with IC order has the highest transition temperature. We continue the investigation of the magnetic phase transition by studying the competition of different possible types of antiferromagnetic order that arises from the presence of two degenerate nesting instabilities with the ordering vectors (pi,0) and (0,pi). We derive a Ginzburg-Landau free energy from a microscopic two-band model and find that the presence of the experimentally observed stripe phase strongly depends on the number and size of the hole pockets in the system and on the doping. We show that within the picture of a purely magnetically driven nematic phase transition, which breaks the C_4 symmetry and induces the orthorhombic distortion, the nematic phase displays exactly the same dependence on the model parameters as the magnetic stripe phase. We propose that in addition to the purely magnetically driven nematic instability there is a ferro-orbital instability in the system that stabilizes the nematic transition and, thus, explains the experimentally observed robustness of the orthorhombic transition. We argue that including a ferro-orbital instability into the picture may also be necessary to reproduce the transition from simultaneous first-order transitions into an orthorhombic antiferromagnetic state to two separate second-order transitions, which is observed as a function of doping. Finally, a study of the superconducting phase transition inside the antiferromagnetic phase that is observed in some pnictide compounds is presented. We present an approach to calculate the fluctuation-mediated pairing interaction in the spin-density-wave phase of a multiband system, which is based on the random-phase approximation. This approach is applied to a minimal two-band model for the pnictides to study the effect of the various symmetry-allowed bare on-site interactions on the gap symmetry and structure. We find a competition between various even- and odd-parity states and over a limited parameter range a p_x-wave state is the dominant instability. The largest part of the parameter space is dominated by even parity states but the gap structure sensitively depends on the bare interactions. We propose that the experimentally observed transition from a nodeless to a nodal gap can be due to changes in the on-site interaction potentials.

info:eu-repo/classification/ddc/530

ddc:530