Global ETD Search

11	Quantização canônica e integração funcional no modelo esférico médio / Canonical quantization and functional integration in the mean spherical mode Paula Fernanda Bienzobaz 16 April 2012 (has links) O modelo esférico desempenha um papel importante na mecânica estatística, pois ele permite a realização de cálculos exatos para estudar o comportamento crítico. Diferentes soluções do modelo esférico têm sido usadas para estudar o comportamento crítico de uma grande variedade de sistemas (com diversos tipos de desordem, com interações competitivas, de curto e de longo alcance, ferro e antiferromagnéticas, além de muitas outras situações). As soluções desses modelos apresentam uma série de anomalias a baixas temperaturas, inclusive resultados que contradizem a terceira lei da termodinâmica. Na década de 70, foi sugerido que esse comportamento anômalo a temperaturas muito baixas seria corrigido pela introdução de flutuações quânticas, que não eram levadas em conta nas soluções clássicas. De fato, a partir da quantização do modelo esférico e possível corrigir esse comportamento. Utilizamos então dois métodos distintos de quantização - quantização canônica e representação em termos de integrais funcionais - para construir versões quânticas do modelo esférico clássico, que podem ser investigadas analiticamente. Mostramos que essas formulações quânticas conduzem aos mesmos resultados. Em particular, analisamos as propriedades termodinâmicas de um modelo esférico médio\" quântico nas seguintes situações: (i) com inteirações de longo alcance, do tipo campo médio, que deve constituir um dos sistemas mais simples exibindo uma transição de fase quântica; (ii) com interações competitivas, entre primeiros e segundos vizinhos, numa situação em que ocorre um ponto multicrítico de Lifshitz; (iii) na presença de interações de longo alcance, tipo campo médio, e de um campo aleatório com média nula; (iv) na presença de desordem de sítios, como nos modelos de van Hemmen para um vidro de spin ou de Hopfield para uma rede neural com poucos padrões. Em todos esses casos há correção do comportamento anômalo a baixas temperaturas. Obtemos diagramas de fases e estudamos em cada caso a natureza das fases ordenadas. / The spherical model plays an important role in statistical mechanics, since it is amenable to exact calculations to investigate the critical behavior. Solutions of the spherical model have been used to investigate the critical behavior of a large variety os systems (with different types of disorder, with competing interactions, of short and long range, of ferro and antiferromagnetic nature, and many other situations). Solutions of these model systems display a number of anomalies at low temperatures, which include some violations of the third law of thermodynamics. In the seventies, it has been suggested that this anomalous behavior at very low temperatures would be corrected by the introduction of quantum uctuations, which were not taken into account by the classical solutions. In fact, the quantization of the spherical model leads to the correction of these effects. We then use two different methods of quantization, canonical quantization and representation in terms of functional integrals, which are still amenable to exact analytical calculations. We show that these quantum formulations lead to the same results. In particular, we analyze the thermodynamic properties of a quantum \\mean spherical model\" in the following situations: (i) with long-range, mean-field, interactions, which is perhaps the simplest model system that exhibits a quantum phase transition; (ii) with competing interactions between first and second neighbors, in which case there should be a Lifshitz multicritical point; (iii) in the presence of long-range interactions and of a random field of zero mean value; (iv) in the presence of disorder, such as the van Hemmen model for a spin glass or the Hopfield model for a neural network with just a few patterns. In all of these cases the anomalous behavior is corrected at low temperatures. We obtain a number of phase diagrams, and discuss the nature of the ordered phases. Modelo esférico classical and quantum phase transitions Spherical model
12	Quantum Fluctuations Across the Superconductor-Insulator Transition Khan, Hasan 04 September 2019 (has links) No description available. Physics Theoretical Physics superconductivity quantum phase transitions critical phenomena monte carlo
13	NUMERICAL STUDIES OF FRUSTRATED QUANTUM PHASE TRANSITIONS IN TWO AND ONE DIMENSIONS Thesberg, Mischa 11 1900 (has links) This thesis, comprising three publications, explores the efficacy of novel generalization of the fidelity susceptibility and their numerical application to the study of frustrated quantum phase transitions in two and one dimensions. Specifically, they will be used in exact diagonalization studies of the various limiting cases of the anisotropic next-nearest neighbour triangular lattice Heisenberg model (ANNTLHM). These generalized susceptibilities are related to the order parameter susceptibilities and spin stiffness and are believed to exhibit similar behaviour although with greater sensitivity. This makes them ideal for numerical studies on small systems. Additionally, the utility of the excited-state fidelity and twist boundary conditions will be explored. All studies are done through numerical exact diagonalization. In the limit of interchain couplings going to zero the ANNTLHM reduces to the well studied $J_1-J_2$ chain with a known, difficult to identify, BKT-type transition. In the first publication of this work the generalized fidelity susceptibilities introduced therein are shown to be able to identify this transition as well as characterize the already understood phases it straddles. The second publication of this work then seeks to apply these generalized fidelity susceptibilities, as well as the excited-state fidelity, to the study of the general phase diagram of the ANNTLHM. It is shown that the regular and excited-state fidelities are useful quantities for the mapping of novel phase diagrams and that the generalized fidelity susceptibilities can provide valuable information as to the nature of the phases within the mapped phase regions. The final paper sees the application of twisted boundary conditions to the anisotropic triangular model (next-nearest neighbour interactions are zero). It is demonstrated that these boundary conditions greatly enhance the ability to numerically explore incommensurate physics in small systems. / Thesis / Doctor of Science (PhD)
14	Dynamic Fidelity Susceptibility and its Applications to Out-of-Equilibrium Dynamics in Driven Quantum Systems Richards, Matt January 2019 (has links) In this thesis we introduce a new quantity which we call the dynamic fidelity susceptibility (DFS). We show that it is relevant to out-of-equilibrium dynamics in many-particle quantum systems, taking the problem of an impurity in a Bosonic Josephson junction, and the transverse field Ising model, as examples. Both of these systems feature quantum phase transitions in their ground states and understanding the dynamics near such critical points is currently an active area of research. In particular, sweeping a system through a quantum critical point at finite speed leads to non-adiabatic dynamics. A simple theoretical tool for describing such a scenario is the celebrated Kibble-Zurek theory which predicts that the number of excitations is related to the speed of sweep via the phase transition’s critical exponents at equilibrium. Another theoretical tool, useful in describing the static properties of quantum phase transitions, is the fidelity susceptibility. Our DFS generalizes the concept of fidelity susceptibility to nonequilibrium dynamics, reproducing its results in the static limit, whilst also displaying universal scaling properties, akin to those found in Kibble-Zurek theory, in the non-adiabatic regime. Furthermore, we show that the DFS is the same quantity as the time-dependent quantum Fisher information which provides a measure of multi-partite entanglement, as well as being closely related to out-of-time-order correlators (OTOCs). / Thesis / Master of Science (MSc) Quantum Dynamics Quantum Phase Transitions Universal Dynamics Fidelity Susceptibility Adiabatic Dynamic Fidelity Susceptibility
15	Magnetic quantum phase transitions: 1/d expansion, bond-operator theory, and coupled-dimer magnets Joshi, Darshan Gajanan 02 March 2016 (has links) (PDF) In the study of strongly interacting condensed-matter systems controlled microscopic theories hold a key position. Spin-wave theory, large-N expansion, and $epsilon$-expansion are some of the few successful cornerstones. In this doctoral thesis work, we have developed a novel large-$d$ expansion method, $d$ being the spatial dimension, to study model Hamiltonians hosting a quantum phase transition between a paramagnet and a magnetically ordered phase. A highlight of this technique is that it can consistently describe the entire phase diagram of the above mentioned models, including the quantum critical point. Note that most analytical techniques either efficiently describe only one of the phases or suffer from divergences near the critical point. The idea of large-$d$ formalism is that in this limit, non-local fluctuations become unimportant and that a suitable product state delivers exact expectation values for local observables, with corrections being suppressed in powers of $1/d$. It turns out that, due to momentum summation properties of the interaction structure factor, all diagrams are suppressed in powers of $1/d$ leading to an analytic expansion. We have demonstrated this method in two important systems namely, the coupled-dimer magnets and the transverse-field Ising model. Coupled-dimer magnets are Heisenberg spin systems with two spins, coupled by intra-dimer antiferromagnetic interaction, per crystallographic unit cell (dimer). In turn, spins from neighboring dimers interact via some inter-dimer interaction. A quantum paramagnet is realized for a dominant intra-dimer interaction, while a magnetically ordered phase exists for a dominant (or of the same order as intra-dimer interaction) inter-dimer interaction. These two phases are connected by a quantum phase transition, which is in the Heisenberg O(3) universality class. Microscopic analytical theories to study such systems have been restricted to either only one of the phases or involve uncontrolled approximations. Using a non-linear bond-operator theory for spins with S=$1/2$, we have calculated the $1/d$ expansion of static and dynamic observables for coupled dimers on a hypercubic lattice at zero temperature. Analyticity of the $1/d$ expansion, even at the critical point, is ensured by correctly identifying suitable observables using the mean-field critical exponents. This method yields gapless excitation modes in the continuous symmetry broken phase, as required by Goldstone\'s theorem. In appropriate limits, our results match with perturbation expansion in small ratio of inter-dimer and intra-dimer coupling, performed using continuous unitary transformations, as well as the spin-wave theory for spin-$1/2$ in arbitrary dimensions. We also discuss the Brueckner approach, which relies on small quasiparticle density, and derive the same $1/d$ expansion for the dispersion relation in the disordered phase. Another success of our work is in describing the amplitude (Higgs) mode in coupled-dimer magnets. Our novel method establishes the popular bond-operator theory as a controlled approach. In $d=2$, the results from our calculations are in qualitative agreement with the quantum Monte Carlo study of the square-lattice bilayer Heisenberg AF spin-$1/2$ model. In particular, our results are useful to identify the amplitude (Higgs) mode in the QMC data. The ideas of large-$d$ are also successfully applied to the transverse-field Ising model on a hypercubic lattice. Similar to bond operators, we have introduced auxiliary Bosonsic operators to set up our method in this case. We have also discussed briefly the bilayer Kitaev model, constructed by antiferromagnetically coupling two layers of the Kitaev model on a honeycomb lattice. In this case, we investigate the dimer quantum paramagnetic phase, realized in the strong inter-layer coupling limit. Using bond-operator theory, we calculate the mode dispersion in this phase, within the harmonic approximation. We also conjecture a zero-temperature phase diagram for this model. Quanten Phasenübergänge quanten spin modell frustriert magnetismus quantum phase transitions quantum spin model frustrated magnetism ddc:530 rvk:UG 3800
16	Zigzag Phase Transition in Quantum Wires and Localization in the Inhomogeneous One-Dimensional Electron Gas Mehta, Abhijit C. January 2013 (has links) <p>In this work, we study two important themes in the physics of the interacting one-dimensional (1D) electron gas: the transition from one-dimensional to higher dimensional behavior, and the role of inhomogeneity. The interplay between interactions, reduced dimensionality, and inhomogeneity drives a rich variety of phenomena in mesoscopic physics. In 1D, interactions fundamentally alter the nature of the electron gas, and the homogeneous 1D electron gas is described by Luttinger Liquid theory. We use Quantum Monte Carlo methods to study two situations that are beyond Luttinger Liquid theory --- the quantum phase transition from a linear 1D electron system to a quasi-1D zigzag arrangement, and electron localization in quantum point contacts. </p><p>Since the interacting electron gas has fundamentally different behavior in one dimension than in higher dimensions, the transition from 1D to higher dimensional behavior is of both practical and theoretical interest. We study the first stage in such a transition; the quantum phase transition from a 1D linear arrangement of electrons in a quantum wire to a quasi-1D zigzag configuration, and then to a liquid-like phase at higher densities. As the density increases from its lowest values, first, the electrons form a linear Wigner crystal; then, the symmetry about the axis of the wire is broken as the electrons order in a quasi-1D zigzag phase; and, finally, the electrons form a disordered liquid-like phase. We show that the linear to zigzag phase transition occurs even in narrow wires with strong quantum fluctuations, and that it has characteristics which are qualitatively different from the classical transition.</p><p>Experiments in quantum point contacts (QPC's) show an unexplained feature in the conductance known as the ``0.7 Effect''. The presence of the 0.7 effect is an indication of the rich physics present in inhomogeneous systems, and we study electron localization in quantum point contacts to evaluate several different proposed mechanisms for the 0.7 effect. We show that electrons form a Wigner crystal in a 1D constriction; for sharp constriction potentials the localized electrons are separated from the leads by a gap in the density, while for smoother potentials, the Wigner crystal is smoothly connected to the leads. Isolated bound states can also form in smooth constrictions if they are sufficiently long. We thus show that localization can occur in QPC's for a variety of potential shapes and at a variety of electron densities. These results are consistent with the idea that the 0.7 effect and bound states observed in quantum point contacts are two distinct phenomena.</p> / Dissertation Condensed matter physics Luttinger Liquid one dimensional electron gas quantum monte carlo quantum phase transitions quantum point contacts quantum wires
17	DECONFINED QUANTUM CRITICALITY IN 2D SU(N) MAGNETS WITH ANISOTROPY D'Emidio, Jonathan 01 January 2017 (has links) In this thesis I will outline various quantum phase transitions in 2D models of magnets that are amenable to simulation with quantum Monte Carlo techniques. The key player in this work is the theory of deconfined criticality, which generically allows for zero temperature quantum phase transitions between phases that break distinct global symmetries. I will describe models with different symmetries including SU(N), SO(N), and "easy-plane" SU(N) and I will demonstrate how the presence or absence of continuous transitions in these models fits together with the theory of deconfined criticality. SU(N) SO(N) Quantum Magnetism Quantum Phase Transitions Deconfined Criticality Quantum Monte Carlo Condensed Matter Physics
18	THE ENTANGLEMENT ENTROPY NEAR LIFSHITZ QUANTUM PHASE TRANSITIONS & THE EMERGENT STATISTICS OF FRACTIONALIZED EXCITATIONS Rodney, Marlon A. 10 1900 (has links) <p>In Part I, the relationship between the topology of the Fermi surface and the entanglement entropy S is examined. Spinless fermionic systems on one and two dimensional lattices at fixed chemical potential are considered. The lattice is partitioned into sub-system of length L and environment, and the entanglement of the subsystem with the environment is calculated via the correlation matrix. S is plotted as a function of the next-nearest or next-next nearest neighbor hopping parameter, t. In 1 dimension, the entanglement entropy jumps at lifshitz transitions where the number of Fermi points changes. In 2 dimensions, a neck-collapsing transition is accompanied by a cusp in S, while the formation of electron or hole-like pockets coincides with a kink in the S as a function of the hopping parameter. The entanglement entropy as a function of subsystem length L is also examined. The leading order coefficient of the LlnL term in 2 dimensions was seen to agree well with the Widom conjecture. Of interest is the difference this coefficient and the coefficient of the term linear in L near the neck-collapsing point. The leading order term changes like \|t-t<sub>c</sub>\|<sup>1/2</sup> whereas the first sub-leading term varies like \|t-t<sub>c</sub>\|<sup>1/3</sup>, where t<sub>c</sub> is the critical value of the hopping parameter at the transition.</p> <p>In Part II, we study the statistics of fractionalized excitations in a bosonic model which describes strongly interacting excitons in a N-band insulator. The elementary excitations of this system are strings, in a large N limit. A string is made of a series of bosons whose flavors are correlated such that the end points of a string carries a fractionalized flavor quantum number. When the tension of a string vanishes, the end points are deconfined. We determine the statistics of the fractionalized particles described by the end points of strings. We show that either bosons or Fermions can arise depending on the microscopic coupling constants. In the presence of the cubic interaction in the Hamiltonian as the only higher order interaction term, it was shown that bosons are emergent. In the presence of the quartic interaction with a positive coupling constant, it was revealed that the elementary excitations of the system possess Fermion statistics.</p> / Master of Science (MSc) entanglement entropy lifshitz quantum phase transitions fermi surface topology fractionalization Condensed Matter Physics Quantum Physics Condensed Matter Physics
19	Neutron Scattering Studies of Magnetic Oxides based on Triangular Motifs Fritsch, Katharina 04 1900 (has links) <p>The following dissertation presents neutron scattering studies on three specific magnetic insulating oxide materials whose lattice is based on triangular structural motifs. Each of the three materials studied, LuCoGaO<sub>4</sub>, Co<sub>3</sub>V<sub>2</sub>O<sub>8</sub> and Tb<sub>2</sub>Ti<sub>2</sub>O<sub>7</sub>, displays an interesting disordered ground state that is reached by different mechanisms: site disorder, geometric frustration, and quantum fluctuations induced by a transverse magnetic field. The main focus of this work is the characterization of the resulting magnetic ground states and magnetic excitations within these systems.</p> <p>Chapters 3, 4 and 5 contain original work in the form of six research articles that have either been published or have been prepared for publication in peer-reviewed journals.</p> <p>Chapter 3 describes studies of the quasi two-dimensional triangular layered antiferromagnet LuCoGaO<sub>4</sub>. This material is found to exhibit a spin glass ground state as a result of geometrical frustration and site disorder inherent in this system. Below the freezing temperature, this system exhibits static, two-dimensional correlations consistent with frozen short-range correlated regions in the plane of the bilayers that extend over roughly five unit cells. The dynamic correlations reveal typical spin glass behavior upon cooling. Furthermore, a resonant gapped spin-wave-like excitation is observed, that can be related to the anisotropy in the system. Such an excitation is relatively uncommon in spin glasses and has been studied for the first time in such detail.</p> <p>Chapter 4 is concerned with the study of the kagome staircase system Co<sub>3</sub>V<sub>2</sub>O<sub>8</sub>. While prone to geometrical frustration due to its underlying kagome structural motif, this material is characterized by predominantly ferromagnetic interactions that lead to an unfrustrated, ferromagnetic ground state. In this chapter, departures from this conventional ground state by different disordering mechanisms are investigated. The first part focuses on the effects of site disorder by introducing quenched nonmagnetic impurities into the system. The growth of single crystals of (Co<sub>1-x</sub>Mg<sub>x</sub>)<sub>3</sub>V<sub>2</sub>O<sub>8</sub> is reported. These crystals reveal that the ferromagnetic ground state is very sensitive to doping, and show that a low doping concentration of 19% leads to a suppression of the ferromagnetic ground state below 1.5 K. This could be understood as percolation problem on the quasi two-dimensional kagome lattice including site and bond percolation. The second part focuses on the influence of a transverse magnetic field on the ground state of Ising spins, introducing quantum fluctuations that lead to quantum phase transitions at ~6.25, 7 and 13 T. The observed quantum phase transitions are characterized by distinct changes in the magnetic structure and their associated spin excitation spectra.</p> <p>Chapter 5 presents studies on the pyrochlore antiferromagnet Tb<sub>2</sub>Ti<sub>2</sub>O<sub>7</sub>, which is a proposed spin liquid candidate but whose actual ground state is still the topic of current debate. The ground state of Tb<sub>2</sub>Ti<sub>2</sub>O<sub>7</sub> was revisited by neutron scattering measurements, revealing a new phase in the low temperature low field phase diagram that can be described as a frozen antiferromagnetic spin ice that exhibits distinct elastic and inelastic scattering features.</p> / Doctor of Philosophy (PhD) neutron scattering magnetic oxides crystal growth geometric frustration spin glasses quantum phase transitions Condensed Matter Physics Condensed Matter Physics
20	Efeitos da aperiodicidade sobre as transições quânticas em cadeias XY / Effects of aperiodicity on the quantum transitions in XY chains Oliveira Filho, Fleury Jose de 08 April 2011 (has links) Neste trabalho realizo uma adaptação do método de Ma, Dasgupta e Hu para o estudo e caracterização das transições de fase quânticas, induzidas por um campo transverso, em cadeias XY de spins 1/2, unidimensionais e aperiódicas, no espírito da adaptação correspondente para cadeias XXZ. O presente trabalho determina de forma analítica uma série de expoentes críticos associados às transições ferro-paramagnéticas do sistema, e dá pistas quanto à natureza das estruturas presentes no estado fundamental. Os resultados são então testados pelo emprego da técnica de férmions livres, da análise de nite size scaling e, no limite de Ising, de resultados extraídos do mapeamento do problema em uma caminhada aleatória. / We employ an adaptation of the Ma, Dasgupta, Hu method in order to analyze the quantum phase transition, induced by a transversal magnetic eld, at spin-1/2 aperiodic XY chains, in analogy to the corresponding adaptation for XXZ chains. We derive analytical expressions for some cri tical exponents related with the ferro-paramagnetic transitions, and shed light onto the nature of the ground state structures. The main results obtained by this approach were tested by the free-fermion method, nite-size scaling analyses and, at the Ising limit of the model, by using results derived from a mapping to a random-walk problem. 1. Mecânica Estatística Quântica 1. Quantum Statistical Mechanics 2. Modelo XY 2. XY Model 3. Aperiodic Systems 3. Sistemas Aperiódicos 4. Quantum Phase Transitions. 4. Transições de Fase Quânticas.

Search results