Nonequilibrium phenomena and dynamical controls in strongly correlated quantum systems driven by AC and DC electric fields / 交流・直流電場に駆動された強相関電子系における非平衡現象と動的制御

Takasan, Kazuaki

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第21548号 / 理博第4455号 / 新制||理||1640(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 川上 則雄, 教授 田中 耕一郎, 教授 前野 悦輝 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

Nonequilibrium phenomena

Strongly correlated quantum systems

Topological superconductivity

Heavy fermion systems

Quantum spin liquid

400

Theoretical study of correlated topological insulators / 相関効果をもつトポロジカル絶縁体の理論的研究

Yoshida, Tsuneya

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18062号 / 理博第3940号 / 新制||理||1568(附属図書館) / 30920 / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 川上 則雄, 教授 石田 憲二, 准教授 藤本 聡 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

strongly correlated systems

topological insulators

dynamical mean field theory

density matrix renormalization group

400

Strongly Correlated Systems, Transport, Entanglement, and Dynamics

Javanmard, Younes

15 February 2019

Strongly correlated systems, i.e., quantum materials for which the interactions between its constituents are strong, are good candidates for the development of applications based on quantum-mechanical principles, such as quantum computers. Two paradigmatic models of strongly correlated systems are heavy-fermionic systems and one-dimensional spin-12 systems, with and without quenched disorder. In the past decade, improvement in computational methods and a vast enhancement in computational power has made it possible to study these systems in a a non-perturbative manner. In this thesis we present state-of-the-art numerical methods to investigate the properties of strongly correlated systems, and we apply these methods to solve a couple of selected problems in quantum condensed matter theory. We start by revisiting the phase diagram of the Falicov-Kimball model on the square lattice which can be considered as a heavy-fermionic systems. This model describes an interplay between conduction electrons and heavy electrons and reveals several distinct metal-insulator phase transitions. Using a lattice Monte-Carlo method, we study the transport properties of the model. Our analysis describes the role of temperature and interaction strength on the metal-insulator phase transitions in the Falicov-Kimball model. The second part of the thesis investigate the spatial structure of the entanglement in ground and thermal statesof the transverse-field Ising chain. We use the logarithmic negativity as a measure for the entanglement between two disjoint blocks. We investigate how logarithmic negativity depends on the spatial separation between two blocks, which can be viewed as the entanglement analog of a spatial correlation function. We find sharp entanglement thresholds at a critical distance beyond which the logarithmic negativity vanishes exactly and thus the two blocks become unentangled. Our results hold even in the presence of long-ranged quantum correlations, i.e., at the system’s quantum critical point. Using Time-Evolving Block Decimation (TEBD), we explore this feature as a function of temperature and size of the two blocks. We present a simple model to describe our numerical observations. In the last part of this thesis, we introduce an order parameter for a many-body localized spin-glass (MBL-SG) phase. We show that many-body localized spin-glass order can also be detected from two-site reduced density matrices, which we use to construct an eigenstate spin-glass order parameter. We find that this eigenstate spin-glass order parameter captures spin-glass phases in random Ising chains, both in many-body eigenstates as well as in the nonequilibrium dynamics, from a local in time measurement. We discuss how our results can be used to observe MBL-SG order within current experiments in Rydberg atoms and trapped ion systems.

info:eu-repo/classification/ddc/530

ddc:530

Nuclear Magnetic Resonance Study on Multiple Superconducting Phases in UTe₂ / UTe₂の超伝導多重相におけるNMRによる研究

Kinjo, Katsuki

23 March 2023

京都大学 / 新制・課程博士 / 博士(理学) / 甲第24399号 / 理博第4898号 / 新制||理||1700(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 石田 憲二, 教授 松田 祐司, 教授 柳瀬 陽一 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

Superconductivity

Spin-triplet superconductivity

Strongly correlated electron system

Nuclear Magnetic Resonance

400

Novel metallic behavior in topologically non-trivial, quantum critical, and low-dimensional matter:

Heath, Joshuah

January 2021

Thesis advisor: Kevin S. Bedell / We present several results based upon non-trivial extensions of Landau-Fermi liquid theory. First proposed in the mid-20th century, the Fermi liquid approach assumes an adiabatic “switching-on” of the interaction, which allows one to describe the collective excitations of the many-body system in terms of weakly-interacting quasiparticles and quasiholes. At its core, Landau-Fermi liquid theory is often considered a perturbative approach to study the equilibrium thermodynamics and out-of-equilibrium response of weakly-correlated itinerant fermions, and therefore non-trivial extensions and consequences are usually overlooked in the contemporary literature. Instead, more emphasis is often placed on the breakdown of Fermi liquid theory, either due to strong correlations, quantum critical fluctuations, or dimensional constraints. After a brief introduction to the theory of a Fermi liquid, I will first apply the Landau quasiparticle paradigm to the theory of itinerant Majorana-like fermions. Defined as fermionic particles which are their own anti-particle, traditional Majorana zero modes found in topological materials lack a coherent number operator, and therefore do not support a Fermi liquid-like ground state. To remedy this, we will apply a combinatorical approach to build a statistical theory of self-conjugate particles, explicitly showing that, under this definition, a filled Fermi surface exists at zero temperature. Landau-Fermi liquid theory is then used to describe the interacting phase of these Majorana particles, from which we find unique signatures of zero sound in addition to exotic, non-analytic contributions to the specific heat. The latter is then exploited as a “smoking-gun” signature for Majorana-like excitations in the candidate Kitaev material Ag3LiIr2O6, where experimental measurements show good agreement with a sharply-defined, “Majorana-Fermi surface” predicted in the underlying combinatorial treatment. I will then depart from Fermi liquid theory proper to tackle the necessary conditions for the applicability of Luttinger’s theorem. In a nutshell, Luttinger’s theorem is a powerful theorem which states that the volume of phase space contained in the Fermi surface is invariant with respect to interaction strength. In this way, whereas Fermi liquid only describes fermionic excitations near the Fermi surface, Luttinger’s theorem describes the fermionic degrees of freedom throughout the entire Fermi sphere. We will show that Luttinger’s theorem remains valid only for certain frequency and momentum-dependencies of the self-energy, which correlate to the exis- tence of a generalized Fermi surface. In addition, we will show that the existence of a power-law Green’s function (a unique feature of “un-particle” systems and a proposed characteristic of the pseudo-gap phase of the cuprate superconductors) forces Luttinger’s theorem and Fermi liquid theory to be mutually exclusive for any non-trivial power of the Feynman propagator. Finally, we will return to Landau-Fermi liquid theory, and close with novel out-of-equilibrium behavior and stability in unconventional Fermi liquids. First, we will consider a perfectly two- dimensional Fermi liquid. Due to the reduction in dimension, the traditional mode expansion in terms of Legendre polynomials is modified to an expansion in terms of Chebyshev polynomials. The resulting orthogonality conditions greatly modifies the stability and collective modes in the 2D system. Second, we will look at a Fermi liquid in the presence of a non-trivial gauge field. The existence of a gauge field will effectively shift the Fermi surface in momentum space, resulting in, once again, a modified stability condition for the underlying Fermi liquid. Supplemented with a modernized version of Mermin’s condition for the propagation of zero sound, we outline the full effects a spin symmetric or anti-symmetric gauge would have on a Fermi liquid ground state. / Thesis (PhD) — Boston College, 2021. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Physics.

Fermi liquid theory

Luttinger's theorem

Majorana fermions

Quantum critical points

Strongly correlated materials

Two-dimensional materials

Towards Quantum Simulation of the Sachdev–Ye–Kitaev Model

Uhrich, Philipp Johann

24 July 2023

Analogue quantum simulators have proven to be an extremely versatile tool for the study of strongly-correlated condensed matter systems both near and far from equilibrium. An enticing prospect is the quantum simulation of non- Fermi liquids which lack a quasiparticle description and feature prominently in the study of strange metals, fast scrambling of quantum information, as well as holographic quantum matter. Yet, large-scale laboratory realisations of such systems remain outstanding. In this thesis, we present a proposal for the analogue quantum simulation of one such system, the Sachdev–Ye–Kitaev (SYK) model, using cavity quantum electrodynamics (cQED). We discuss recent experimental advances in this pursuit, and perform analysis of this and related models. Through a combination of analytic calculations and numeric simulations, we show how driving a cloud of fermionic atoms trapped in a multi- mode optical cavity, and subjecting it to a spatially disordered AC-Stark shift, can realise an effective model which retrieves the physics of the SYK model, with random all-to-all interactions and fast scrambling. Working towards the SYK model, we present results from a recent proof-of-principle cQED experiment which implemented the disordered light-shift technique to quantum simulate all- to-all interacting spin models with quenched disorder. In this context, we show analytically how disorder-driven localisation can be extracted from spectroscopic probes employed in cQED experiments, despite their lack of spatially resolved information. Further, we numerically investigate the post-quench dynamics of the SYK model, finding a universal, super-exponential equilibration in the disorder-averaged far-from-equilibrium dynamics. These are reproduced analytically through an effective master equation. Our work demonstrates the increasing capabilities of cQED quantum simulators, highlighting how these may be used to study the fascinating physics of holographic quantum matter and other disorder models in the lab.

Pairing, paramagnetism and prethermalization in strongly correlated low-dimensional quantum systems

Robinson, Neil Joe

January 2014

Quasi-one-dimensional quantum models are ideal for theoretically exploring the physical phenomena associated with strong correlations. In this thesis we study three examples where strong correlations play an important role in the static or dynamic properties of the system. Firstly, we examine the behaviour of a doped fermionic two-leg ladder in which umklapp interactions are present. Such interactions arise at special band fillings and can be induced by the formation of charge density wave order in an array of two-leg ladders with long-range (three-dimensional) interactions. For the umklapp which arises from the half-filling of one of the bands, we show that the low-energy theory has a number of phases, including a strong coupling regime in which the dominant fluctuations are superconducting in nature. These superconducting fluctuations carry a finite wave vector – they are the one-dimensional analogue of Fulde-Ferrell-Larkin-Ovchinnikov superconductivity. In a second example, we consider a quantum spin model which captures the essential one-dimensional physics of CoNb₂O₆, a quasi-one-dimensional Ising ferromagnet. Motivated by high-resolution inelastic neutron scattering experiments, we calculate the dynamical structure in the paramagnetic phase and show that a small misalignment of the transverse field can lead to quasi-particle breakdown – a surprising broadening in the single particle mode observed in experiment. Finally, we study the out-of-equilibrium dynamics of a model with tuneable integrability breaking. When integrability is broken by the presence of weak interactions, we show that the system relaxes to a non-thermal state on intermediate time scales, the so-called “prethermalization plateau”. We describe the approximately stationary behaviour in this regime by constructing a generalised Gibbs ensemble with charges deformed to leading order in perturbation theory. Expectation values of these charges are time-independent, but interestingly the charges do not commute with the Hamiltonian to leading order in perturbation theory. Increasing the strength of the integrability breaking interactions leads to behaviour compatible with thermalisation. In each case we use a combination of perturbative analytical calculations and non-perturbative numerical computations to study the problem at hand.

537.6

De la frustration et du désordre dans les chaînes et les échelles de spins quantiques / Frustration and disorder in quantum spin chains and ladders

Lavarelo, Arthur

19 July 2013

Dans les systèmes de spins quantiques, la frustration et la basse dimensionnalité génèrent des fluctuations quantiques et donnent lieu à des phases exotiques. Cette thèse étudie un modèle d'échelle de spins avec des couplages frustrants le long des montants, motivé par les expériences sur le cuprate BiCu$_2$PO$_6$. Dans un premier temps, on présente une méthode variationnelle originale pour décrire les excitations de basse énergie d'une seule chaîne frustrée. Le diagramme de phase de deux chaînes couplées est ensuite établi à l'aide de méthodes numériques. Le modèle exhibe une transition de phase quantique entre une phase dimérisée est une phase à liens de valence résonnants (RVB). La physique de la phase RVB et en particulier l'apparition de l'incommensurabilité sont étudiées numériquement et par un traitement en champ moyen. On étudie ensuite les effets d'impuretés non-magnétiques sur la courbe d'aimantation et la loi de Curie à basse température. Ces propriétés magnétiques sont tout d'abord discutées à température nulle à partir d'arguments probabilistes. Puis un modèle effectif de basse énergie est dérivé dans la théorie de la réponse linéaire et permet de rendre compte des propriétés magnétiques à température finie. Enfin, on étudie l'effet d'un désordre dans les liens, sur une seule chaîne frustrée. La méthode variationnelle, introduite dans le cas non-désordonné, donne une image à faible désordre de l'instabilité de la phase dimérisée, qui consiste en la formation de domaines d'Imry-Ma délimités par des spinons localisés. Ce résultat est finalement discuté à la lumière de la renormalisation dans l'espace réel à fort désordre. / In quantum spins systems, frustration and low-dimensionality generate quantum fluctuations and give rise to exotic quantum phases. This thesis studies a spin ladder model with frustrating couplings along the legs, motivated by experiments on cuprate BiCu$_2$PO$_6$. First, we present an original variational method to describe the low-energy excitations of a single frustrated chain. Then, the phase diagram of two coupled chains is computed with numerical methods. The model exhibits a quantum phase transition between a dimerized phase and resonating valence bound (RVB) phase. The physics of the RVB phase and in particular the onset of incommensurability are studied numerically and by a mean-field treatment. Afterwards, we study the effects of non-magnetic impurities on the magnetization curve and the Curie law at low temperature. These magnetic properties are first discussed at zero temperature with probability arguments. Then a low-energy effective model is derived within the linear response theory and is used to explain the magnetic properties at finite temperature. Eventually, we study the effect of bonds disorder, on a single frustrated chain. The variational method introduced in the non-disordered case gives a low disorder picture of the dimerized phase instability, which consists in the formation of Imry-Ma domains delimited by localized spinons. This result is finally discussed in the light of the strong disorder real space renormalization.

Électrons fortement corrélés

Magnétisme quantique

Chaînes de spins

Frustration

Désordre

Strongly correlated electrons

Quantum magnetism

Spin chains

Frustration

Disorder

Transitions de phases magnétiques dans des systèmes de spins quantiques à basse dimension

Canevet, Emmanuel

16 December 2010

Cette thèse porte sur l'étude de trois systèmes de spins basse dimension par diffraction et diffusion inélastique de neutrons. Dans le composé DMACuCl3, les mesures macroscopiques semblent indiquer la coexistence de deux types de dimères : antiferromagnétique et ferromagnétique. Une étude par diffraction nous a permis de déterminer sa structure magnétique en champ nul qui prouve l'existence des deux dimères de manière irrévocable. Il a été montré que le composé de type Ising BaCo2V2O8 serait le premier système présentant un ordre magnétique incommensurable longitudinal (ICL) sous champ. Tout d'abord, nous avons déterminé la structure magnétique en champ nul. Ensuite, nous avons suivi l'évolution du vecteur de propagation en fonction du champ magnétique caractérisant ainsi l'entrée dans la phase ICL à Hc = 3.9 T. La détermination de l'ordre magnétique de la phase ICL confirme que BaCo2V2O8 est le premier composé présentant un ordre magnétique colinéaire à la direction du champ. Il a été montré que le composé organique DF5PNN est bien décrit à basse température par des chaînes de spins à couplages alternés. Or la structure cristallographique connue à température ambiante implique des couplages uniformes. Notre étude par diffraction montre l'existence d'une transition structurale à basse température (Tc = 450 mK) faisant passer du groupe d'espace C2/c à Pc, et expliquant la nature alternée des interactions. Nous avons également caractérisé une transition structurale induite sous champ (Hc = 1.1 T) faisant revenir le groupe d'espace à C2/c. Cette transition implique un retour à l'uniformité des échanges, ce que nous avons confirmé en étudiant les excitations magnétiques.

Magnétisme basse dimension

Chaîne de spins

Diffusion neutronique

Diffraction

Structure magnétique

Excitations magnétiques

Propriétés magnétiques de systèmes à deux dimensions : système frustré de spins sur réseau carré et propriétés magnétiques de systèmes finis de graphène.

Feldner, Hélène

07 July 2011

L'objet de cette thèse est l'étude des propriétés magnétiques de deux systèmes bidimensionels. Le premier correspond à des composés de cuprate ou vanadate qui peuvent être modélisés par un système de spins sur réseau carré et un modèle d'Heisenberg à trois couplages, avec un premier couplage ferromagnétique et des couplages deuxièmes et troisièmes voisins antiferromagnétiques. Le système ainsi obtenu constitue un système frustré. Après obtention du diagramme de phase classique en fonction des couplages, nous avons étudié l'effet sur celui-ci des fluctuations quantiques par la méthode des bosons de Holstein-Primakov et celle des bosons de Schwinger. Le deuxième type de système auquel nous nous sommes intéressés sont les systèmes finis de graphène. Pour étudier ce matériau, nous avons utilisé une approximation champ moyen du modèle d'Hubbard. Dans un premier temps nous avons retrouvé des résultats déjà connus confirmant ainsi une implémentation correcte de notre modèle. Nous avons ensuite cherché à établir la précision de cette méthode en comparant les résultats obtenus par cette méthode avec ceux obtenus par diagonalisation exacte du modèle et ceux obtenus par simulation Monte Carlo. Et en dernier lieu nous avons mis en évidence une signature dynamique de l'aimantation des bords en zigzag des systèmes finis de graphène.

graphène

système frustré

Onde de spin

approximation champs moyen

Schwinger-bosons