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Showing 41 to 50 of 64 (0.06 seconds)Spelling suggestions: "subject:"quantum month carlo"" "subject:"quantum fonte carlo""
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Étude par Monte Carlo quantique de la transition γ-α du cérium / Quantum Monte Carlo study of the γ-α transition of CeriumDevaux, Nicolas 19 October 2015 (has links)
Les électrons 4f sont fortement localisés et leurs répulsions coulombiennes intersites sont évaluées comme plus larges que leurs largeurs de bande. Parmi tous les lanthanides, le cérium est particulièrement fascinant. Ceci s'explique par la forte hybridation avec les bandes 6s-6p-5d qui se situent toutes au niveau de Fermi. L'origine de l'effondrement du volume lors de la transition isostructurale γ-α est une énigme difficile à résoudre depuis sa découverte en 1927. Expérimentalement, la transition γ-α se réalise seulement à température finie. Récemment, des mesures très précises de diffraction aux rayons X ont confirmé le caractère isotructural (groupe Fm-3m) du premier ordre. À partir des premiers principes, nous avons caractérisé la transition de phase γ-α du cérium par une méthode utilisant une fonction d'onde Jastrow corrélée qui minimise l'énergie variationnelle de l'hamiltonien relativiste scalaire. L'ansatz variationnel traite les corrélations de manière non-perturbative et reproduit les propriétés des deux phases en accord avec l'expérience. Cela prouve que même à température nulle, la transition est toujours du premier ordre avec des paramètres ab initio qui sont sans aucun doute reliés aux mesures obtenues par l'expérience à température finie T. Nous montrons que la transition est liée à un réarrangement complexe de la structure électronique qui affecte en même temps la localisation des orbitales t1u (leur répulsion coulombienne) et le caractère de la liaison chimique. / The 4f electrons are strongly localized and their on-site Coulomb repulsion is large compared to bandwidth. Among all lanthanides, cerium is particularly fascinating, due to the strong hybridization with the 6s-6p-5d bands, all present at the Fermi level. The origin of the cerium volume collapse along the isostructural γ-α transition has been a puzzle since its discovery in 1927. Experimentally, pure cerium undergoes the γ-α transition always at finite temperature T. Recently, very accurate X-ray diffraction measurements undoubtedly confirmed the first-order Fm-3m isostructural character of the transition. The first-order line extrapolates to zero-T at negative pressures. The cerium γ-α phase transition is characterized by means of a many-body Jastrow-correlated wave function, which minimizes the variational energy of the first-principles scalar-relativistic Hamiltonian, and includes correlation effects in a non-perturbative way. Our variational ansatz reproduces the structural properties of the two phases, and proves that even at temperature T = 0 K the system undergoes a first order transition, with ab-initio parameters which are seamlessly connected to the ones measured by experiment at finite T. We show that the transition is related to a complex rearrangement of the electronic structure, with key role played by the localisation of t1u orbitals, which tunes the Coulomb repulsion, and the character of the chemical bond.
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A full-dimensional quantum Monte Carlo study of H5O2+Cho, Hyung Min 17 June 2004 (has links)
No description available.
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Establishing Quantum Monte Carlo and Hybrid Density Functional Theory as Benchmarking Tools for Complex SolidsDriver, Kevin P. 17 March 2011 (has links)
No description available.
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Valence Bond Calculations for Quantum Spin Chains: From Impurity Entanglement and Incommensurate Behaviour to Quantum Monte CarloDeschner, Andreas 04 1900 (has links)
<p>In this thesis I present three publications about the use of<br />valence bonds to gain information about quantum spin systems.<br />Valence bonds are an essential ingredient of low energy states present<br />in many compounds.<br /><br />The first part of this thesis is dedicated to<br />two studies of the antiferromagnetic J<sub>1</sub>-J<sub>2</sub> chain with<br />S=1/2. We show how automated variational calculations based on<br />valence bond states can be performed close to the Majumdar-Ghosh point<br />(MG-point). At this point, the groundstate is a product state of<br />dimers (valence bonds between nearest neighbours). In the dimerized<br />region surrounding the MG-point, we find such variational computations<br />to be reliable.<br /><br />The first publication is about<br />the entanglement properties of an impurity attached to the chain. We show<br />how to use the variational method to calculate the negativity, an<br />entanglement measure between the impurity and a distant part of the<br />chain. We find that increasing the impurity coupling and a<br />minute explicit dimerization, suppress the long-ranged entanglement<br />present in the system for small impurity coupling at the MG-point. <br /><br />The second publication is about a<br />transition from commensurate to incommensurate behaviour and how its<br />characteristics depend on the parity of the length of the chain. The<br />variational technique is used in a parameter regime inaccessible to<br />DMRG. We find that in odd chains, unlike in even chains, a very<br />intricate and interesting pattern of level crossings can be observed. <br /><br />The publication of the second part is about novel worm algorithms for<br />a popular quantum Monte Carlo method called valence bond quantum Monte<br />Carlo (VBQMC). The algorithms are based on the notion of a worm<br />moving through a decision tree. VBQMC is entirely formulated in<br />terms of valence bonds. In this thesis, I explain how the approach<br />of VBQMC can be translated to the S<sub>z</sub>-basis. The algorithms explained<br />in the publication can be applied to this S<sub>z</sub>-method.</p> / Doctor of Philosophy (PhD)
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Path Integral Quantum Monte Carlo Study of Coupling and Proximity Effects in Superfluid Helium-4Graves, Max 01 January 2014 (has links)
When bulk helium-4 is cooled below T = 2.18 K, it undergoes a phase transition to a superfluid, characterized by a complex wave function with a macroscopic phase and exhibits inviscid, quantized flow. The macroscopic phase coherence can be probed in a container filled with helium-4, by reducing one or more of its dimensions until they are smaller than the coherence length, the spatial distance over which order propagates. As this dimensional reduction occurs, enhanced thermal and quantum fluctuations push the transition to the superfluid state to lower temperatures. However, this trend can be countered via the proximity effect, where a bulk 3-dimensional (3d) superfluid is coupled to a low (2d) dimensional superfluid via a weak link producing superfluid correlations in the film at temperatures above the Kosterlitz-Thouless temperature. Recent experiments probing the coupling between 3d and 2d superfluid helium-4 have uncovered an anomalously large proximity effect, leading to an enhanced superfluid density that cannot be explained using the correlation length alone. In this work, we have determined the origin of this enhanced proximity effect via large scale quantum Monte Carlo simulations of helium-4 in a topologically non-trivial geometry that incorporates the important aspects of the experiments. We find that due to the bosonic symmetry of helium-4, identical particle permutations lead to correlations between contiguous spatial regions at a length scale greater than the coherence length. We show that quantum exchange plays a large role in explaining the anomalous experimental results while simultaneously showing how classical arguments fall short of this task.
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Electrons fortement corrélés : de deux dimensions aux hétérostructures / Strongly correlated electrons : from two dimensions to heterostructuresEuverte, Axel 11 October 2013 (has links)
Les propriétés d'électrons en deux dimensions (2D) soulèvent des questions fondamentales qui ont été largement explorées au moyen des techniques théoriques de la matière condensée. L'extension de modèles classiques tel le modèle de Hubbard en 2D, en incluant par exemple plusieurs bandes électroniques, ore la possibilité d'accéder à des phénomèmes plus complexes, comme l'interaction du transport électronique et du magnétisme observé dans les composés de fermions lourds. Ces modèles sont en lien direct avec la question de couches minces couplées, les hétérostructures, qui sont depuis peu l'objet d'intenses recherches et orent la possibilité d'intéressantes applications. Dans ce contexte, nous étudions numériquement diérents syst èmes au moyen de la méthode du Monte Carlo Quantique du Déterminant. Tout d'abord, l'eet de la corrélation électronique dans un isolant de bande est évaluée, montrant en particulier l'absence d'une phase métallique intermédiaire. Un deuxième système est composé de deux bandes électroniques couplées, dans lequel l'eet de la largeur de bande de la partie corrélée est exploré de façon systématique. Finalement, nous étudions une interface métal-isolant, qui présente une phase intermédiaire surprenante lorsque le couplage à l'interface est ajusté. / The properties of electrons in two dimensions (2D) raise fundamental questions that have been extensively explored by condensed matter theory. Extending standard frameworks such as the 2D Hubbard model by accounting for more than one electronic band oers the opportunity to access more complex phenomena, such as the interplay between transport and magnetism found in heavy-fermions materials. Such models are directly connected to the problem of coupled layers in complex materials known as heterostructures, which have been widely studied and synthesized in recent years, and are expected to lead to important applications. In that context, we study numerically several systems, by mean of the Determinant Quantum Monte Carlo Method (DQMC). We rst analyze the eect of electronic correlation in a band insulator, showing in particular the absence of an intermediate metallic phase. A second system consists of two coupled bands that modelize a heavy fermion model, in which the role of the bandwidth of the correlated band is systematically investigated. Finally, we consider the case of a metal-insulator interface, unveiling an intriguing intermediate phase as the interfacial coupling is tuned.
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Backflow and pairing wave function for quantum Monte Carlo methodsLópez Ríos, Pablo January 2016 (has links)
Quantum Monte Carlo (QMC) methods are a class of stochastic techniques that can be used to compute the properties of electronic systems accurately from first principles. This thesis is mainly concerned with the development of trial wave functions for QMC. An extension of the backflow transformation to inhomogeneous electronic systems is presented and applied to atoms, molecules and extended systems. The backflow transformation I have developed typically retrieves an additional 50% of the remaining correlation energy at the variational Monte Carlo level, and 30% at the diffusion Monte Carlo level; the number of parameters required to achieve a given fraction of the correlation energy does not appear to increase with system size. The expense incurred by the use of backflow transformations is investigated, and it is found to scale favourably with system size. Additionally, I propose a single wave function form for studying the electron-hole system which includes pairing effects and is capable of describing all of the relevant phases of this system. The effectiveness of this general wave function is demonstrated by applying it to a particular transition between two phases of the symmetric electron-hole bilayer, and it is found that using a single wave function form gives a more accurate physical description of the system than using a different wave function to describe each phase. Both of these developments are new, and they provide a powerful set of tools for designing accurate wave functions. Backflow transformations are particularly important for systems with repulsive interactions, while pairing wave functions are important for attractive interactions. It is possible to combine backflow and pairing to further increase the accuracy of the wave function. The wave function technology that I have developed should therefore be useful across a very wide range of problems.
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| 48 |
Interplay of Disorder and Transverse-Field Induced Quantum Fluctuations in the LiHo_xY_{1-x}F_4 Ising Magnetic MaterialTabei, Seyed Mohiaddeen Ali January 2008 (has links)
The LiHo_xY_{1-x}F_4 magnetic material in a transverse magnetic
field B_x perpendicular to the Ising spin direction has long been used
to study tunable quantum phase transitions in pure and random disordered systems.
We first present analytical and numerical evidences for the validity of an effective spin-1/2
approach to the description of a general dipolar spin
glass model with strong uniaxial Ising anisotropy and subject to weak
B_x.
We relate this toy model to the LiHo_xY_{1-x}F_4 transverse field Ising material.
We show that an effective spin-1/2
model is able to capture both the qualitative and quantitative aspects of the
physics at small B_x.
After confirming the validity of the effective spin-1/2 approach, we show that the field-induced magnetization along the
x direction,
combined with the local random dilution-induced
destruction of crystalline mirror symmetries
generates, via the predominant dipolar interactions between Ho^{3+} ions,
random fields along the Ising z direction.
This identifies LiHo_xY_{1-x}F_4 in B_x as a new
random field Ising system.
We show that the random fields explain the smearing
of the nonlinear susceptibility at the spin glass transition
with increasing B_x.
In this thesis, we also investigate the phase diagram of non-diluted LiHoF_4 in the presence of B_x, by performing
Monte-Carlo simulations. A previous quantum Monte Carlo (QMC) simulation found that even for small B_x where quantum fluctuations are small, close to the classical critical
point, there is a discrepancy between experiment and the QMC results. We revisit this problem, focusing on
weak B_x close to the classical T_c, using an alternative approach. For small B_x, by applying a so-called cumulant
expansion, the quantum fluctuations around the classical T_c are taken into account perturbatively. We derived an effective
perturbative classical Hamiltonian, on which MC simulations are performed. With this method we
investigate different proposed sources of uncertainty which can affect the numerical results.
We fully reproduce the previous QMC results at small B_x. Unfortunately, we find that
none of the modifications to the microscopic Hamiltonian that we explore are able to provide a B_x-T phase diagram compatible with the experiments in the small
semi-classical B_x regime.
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| 49 |
Interplay of Disorder and Transverse-Field Induced Quantum Fluctuations in the LiHo_xY_{1-x}F_4 Ising Magnetic MaterialTabei, Seyed Mohiaddeen Ali January 2008 (has links)
The LiHo_xY_{1-x}F_4 magnetic material in a transverse magnetic
field B_x perpendicular to the Ising spin direction has long been used
to study tunable quantum phase transitions in pure and random disordered systems.
We first present analytical and numerical evidences for the validity of an effective spin-1/2
approach to the description of a general dipolar spin
glass model with strong uniaxial Ising anisotropy and subject to weak
B_x.
We relate this toy model to the LiHo_xY_{1-x}F_4 transverse field Ising material.
We show that an effective spin-1/2
model is able to capture both the qualitative and quantitative aspects of the
physics at small B_x.
After confirming the validity of the effective spin-1/2 approach, we show that the field-induced magnetization along the
x direction,
combined with the local random dilution-induced
destruction of crystalline mirror symmetries
generates, via the predominant dipolar interactions between Ho^{3+} ions,
random fields along the Ising z direction.
This identifies LiHo_xY_{1-x}F_4 in B_x as a new
random field Ising system.
We show that the random fields explain the smearing
of the nonlinear susceptibility at the spin glass transition
with increasing B_x.
In this thesis, we also investigate the phase diagram of non-diluted LiHoF_4 in the presence of B_x, by performing
Monte-Carlo simulations. A previous quantum Monte Carlo (QMC) simulation found that even for small B_x where quantum fluctuations are small, close to the classical critical
point, there is a discrepancy between experiment and the QMC results. We revisit this problem, focusing on
weak B_x close to the classical T_c, using an alternative approach. For small B_x, by applying a so-called cumulant
expansion, the quantum fluctuations around the classical T_c are taken into account perturbatively. We derived an effective
perturbative classical Hamiltonian, on which MC simulations are performed. With this method we
investigate different proposed sources of uncertainty which can affect the numerical results.
We fully reproduce the previous QMC results at small B_x. Unfortunately, we find that
none of the modifications to the microscopic Hamiltonian that we explore are able to provide a B_x-T phase diagram compatible with the experiments in the small
semi-classical B_x regime.
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| 50 |
Charge properties of cuprates: ground state and excitationsWaidacher, Christoph 03 March 2000 (has links) (PDF)
This thesis analyzes charge properties of (undoped) cuprate compounds from a theoretical point of view. The central question considered here is: How does the dimensionality of the CU-O sub-structure influence its charge degrees of freedom? The model used to describe the Cu-O sub-structure is the three- (or multi-) band Hubbard model. Analytical approaches are employed (ground-state formalism for strongly correlated systems, Mori-Zwanzig projection technique) as well as numerical simulations (Projector Quantum Monte Carlo, exact diagonalization). Several results are compared to experimental data. The following materials have been chosen as candidates to represent different Cu-O sub-structures: Bi2CuO4 (isolated CuO4 plaquettes), Li2CuO2 (chains of edge-sharing plaquettes), Sr2CuO3 (chains of corner-sharing plaquettes), and Sr2CuO2Cl2 (planes of plaquettes). Several results presented in this thesis are valid for other cuprates as well. Two different aspects of charge properties are analyzed: 1) Charge properties of the ground state 2) Charge excitations. (gekürzte Fassung)
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