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Analysis of Topological Chaos in Ghost Rod Mixing at Finite Reynolds Numbers Using Spectral MethodsRao, Pradeep C. 2009 December 1900 (has links)
The effect of finite Reynolds numbers on chaotic advection is investigated for two
dimensional lid-driven cavity flows that exhibit topological chaos in the creeping flow
regime. The emphasis in this endeavor is to study how the inertial effects present
due to small, but non-zero, Reynolds number influence the efficacy of mixing. A
spectral method code based on the Fourier-Chebyshev method for two-dimensional
flows is developed to solve the Navier-Stokes and species transport equations. The
high sensitivity to initial conditions and the exponentional growth of errors in chaotic
flows necessitate an accurate solution of the flow variables, which is provided by the
exponentially convergent spectral methods. Using the spectral coefficients of the basis
functions as solved through the conservation equations, exponentially accurate values
of velocity everywhere in the flow domain are obtained as required for the Lagrangian
particle tracking. Techniques such as Poincare maps, the stirring index based on the
box counting method, and the tracking of passive scalars in the flow are used to
analyze the topological chaos and quantify the mixing efficiency.
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Application of the Space – Time Conservation Element and Solution Element Numerical Method to Flows in Fluid FilmsCioc, Sorin 31 August 2004 (has links)
No description available.
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Une étude numérique des écoulements mono et diphasique inertiels en milieux poreux / Inertial one and two phase flow in porous media, a numerical InvestigationAgnaou, Mehrez 18 December 2015 (has links)
: Ce travail concerne l'écoulement inertiel en milieu poreux rencontré dans diversessituations telles que les écoulements autour des puits pour la récupération pétrolière, lesécoulements dans les réacteurs catalytiques, etc. En régime stationnaire, les différents modèlesmacroscopiques pour décrire ces écoulements inertiels (non-linéaires) demeurent encore sujetsà débat. Ces modèles consistent en une loi de Darcy corrigée de termes dont la dépendancevis à vis de la vitesse de filtration relève du régime d'écoulement. Dans ce travail, une attentionparticulière est portée tout d'abord à l'étude numérique (DNS), sur des structures modèles, de lalimite de stationnarité de l'écoulement monophasique newtonien qui correspond à la premièrebifurcation de Hopf, caractérisée par un nombre de Reynolds critique. La connaissance de cettelimite est cruciale puisqu'elle détermine le domaine de validité des modèles macroscopiquesstationnaires pertinents. Dans un deuxième temps, la dépendance de la déviation (inertielle) àla loi de Darcy par rapport aux propriétés de la structure poreuse (forme des grains, désordre)et à l'orientation de l'écoulement est étudiée dans le cas de structures 2D et 3D. Les propriétéseffectives de la structure à l'échelle macroscopique sont déterminées à partir de la résolutionnumérique des problèmes de fermeture associés au modèle macroscopique obtenu par prisede moyenne des équations de Navier-Stokes. Afin de déceler l'origine de cette déviation et sesdifférentes formes, l'évolution de la structure microscopique de l'écoulement en fonction dunombre de Reynolds est analysée. Plus particulièrement, le rôle des zones de recirculation, etles corrélations avec la courbure des lignes de courant multipliée par l’énergie cinétique localeet la variation de l’énergie cinétique le long de ces lignes sont étudiés. La dernière partie dutravail est consacrée à une étude numérique, toujours dans des situations modèles, de ladéviation à la loi de Darcy généralisée dans le cas de l'écoulement diphasique inertiel. / This work focuses on inertial flow in porous media encountered in differentindustrial situations such as flow around wells in oil recovery, flow in filters and in columns ofreactors for chemical engineering, etc. In stationary flow regime, the different macroscopicmodels describing inertial (non-linear) flow are still discussed. These models consist in theDarcy’s law with correction extra terms whose dependence upon the filtration velocity is afunction of the flow regime. In this work, a particular attention is attributed first to the numericalinvestigation (DNS), on model structures, of the limit of one phase Newtonian stationary flowwhich corresponds to the first Hopf bifurcation, characterized by a critical Reynolds number.The knowledge of this limit is crucial since it establishes the ranges of validity of the relevantmacroscopic stationary models. In a second step, the dependence of the deviation (inertial)from Darcy’s law on the properties of the porous structure (grains shape, disorder) and on theorientation of the flow is analyzed in 2D and 3D situations. The effective properties of thestructure and the flow at the macroscopic scale are obtained from the numerical resolution ofthe closure problems associated to the macroscopic model obtained from an up-scalingprocedure (volume averaging) of the Navier-Stokes equations. In order to identify the origin ofthe deviation and its different forms, the variation of the microscopic flow structure with theReynolds number is analyzed. More specifically, the role of the recirculation zones, and thecorrelations with flow streamlines curvature multiplied by the local kinetic energy and thevariation of the kinetic energy along these lines are studied. The last part of the work isdedicated to a numerical investigation of the deviation from the generalized Darcy’s law in thecase of two phase inertial flow.
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Efeitos geométricos, inerciais e topológicos na condutividade HallSilva, Júlio Eloísio Brandão da 16 March 2017 (has links)
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Previous issue date: 2017-03-16 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / Electromagnetic fields acting on particles have been extensively studied in different areas
of physics. In quantum mechanics for example, effects such as Aharonov-Bohm, Landau levels
and Hall conductivity, have always motivated new papers including analogous inertial models.
Inertial effects play an important role in classical mechanics, but have been largely ignored
in quantum mechanics. However, the analogy between inertial forces on mass particles and
electromagnetic forces on charged particles is not new. Another factor that may influence the
classical and quantum behavior of particles is geometry. An element related to geometry that has
been extensively studied in several areas is the topological defect. Topological defects represent
an interface between areas such as cosmology, gravitation, and condensed matter. Such defects
in condensed matter can be developed through the classical theory of elasticity. However, due
to the interdisciplinarity of this theme, approaches from gravitation can also describe them.
Based on this analogy, the medium formed by a topological defect is characterized by a metric
tensor. From this approach, several problems can be discussed by analyzing the influence of the
topological defect in the solution of the problem. In this work, it will be discussed how magnetic field, rotation and topological defects, especially
the disclination, influence in the Landau Levels and the Hall conductivity for a noninteracting
planar two-dimensional electron gas. First we will discuss the influence of each of
these elements and then the influence of all of them simultaneously. / A atuação de campos eletromagnéticos em partículas têm sido extensivamente estudada em
diferentes áreas da física. Em mecânica quântica por exemplo, efeitos como Aharonov-Bohm,
níveis de Landau e condutividade Hall, têm sempre motivado novos trabalhos inclusive para
modelos análogos inerciais. Os efeitos inerciais desempenham um papel importante na mecânica
clássica, mas tem sido largamente ignorados em mecânica quântica. No entanto, a analogia
entre forças inerciais sobre partículas de massa e forças eletromagnéticas sobre partículas carregadas
não é nova. Um outro fator que pode influenciar no comportamento clássico e quântico
de partículas é a geometria. Um elemento relacionado a geometria e que tem sido bastante
estudado em diversas áreas, é o defeito topológico. Os defeitos topológicos representam uma
interface entre áreas como cosmologia, gravitação e matéria condensada. Tais defeitos em matéria
condensada podem ser desenvolvidos através da teoria clássica da elasticidade. Contudo,
devido a interdisciplinaridade desse tema, abordagens provenientes da gravitação podem também
descrevê-los. Com base nessa analogia, caracteriza-se o meio formado por um defeito
topológico mediante um tensor métrico. A partir dessa abordagem, diversos problemas podem
ser discutidos analisando a influência do defeito topológico na solução do problema.
Nesse trabalho, será discutido como campo magnético, rotação e defeitos topológicos, em
especial a desclinação, influenciam os níveis de Landau e a condutividade Hall para um gás
de elétrons bidimensional planar não interagente. Primeiramente discutiremos a influência de
cada um desses elementos e em seguida a influência de todos simultaneamente. Será mostrado
como a rotação quebra a degenerescência dos níveis de Landau aumentando consequentemente
a condutividade Hall. Será mostrado também que acoplamento dos três elementos gera uma
região para campos magnéticos fracos com sem estados ligados. Com um outro ponto de partida
mostraremos também que a rotação pode ser utilizada para sintonizar a condutividade Hall.
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Níveis de Landau-CoriolisSilva, Júlio Eloísio Brandão da 01 February 2013 (has links)
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Previous issue date: 2013-02-01 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / Inertial effects, such as Coriolis’ and centrifuge forces play an interesting role on classical
mechanics and currently has been largely used in quantum mechanics, including in analogies
with the electromagnetic effects. However, these analogies between the inertial forces on the
massives particules and the electromagnetic forces on charged particles is not new. They were
explored by Aharonov and Carmi in 1970 and by Tsai and Nelson in 1988 in the context of
a rotational quantum phase like an Aharonov-Bohm phase. Based in this analogy, Dattoli and
Quattromini, introduced Coriolis’ analogue quantum states to Landau levels. In 1915, Barnett
had already published a paper about magnetization due to rotation which recently had a renewed
interest applyed to nanostructures. A rotational analogy of the classical Hall effect was proposed
and rotational inertial forces were studied in spintronic. Energy spectra like Landau levels
appear under the action of Coriolis forces when the centrifuge force acting on free electrons
is compensated by a radial electric field. In this work, we will demonstrate effects caused by
rotation and magnetic field in a spinning conductor disc. We will study both the electromagnetic
and inertial interactions simultaneously. Some values to the relation between the magnetic
field and the rotation will be chosen and this will result in Landau-like levels to a system with
resultant force composed by Coriolis’ and magnetic forces. A similar behavior for the energy
spectrum will be found without a magnetic force composing the resultant force. / Efeitos inerciais, tais como a força centrífuga e a de Coriolis, desempenham um papel importante
na mecânica clássica e atualmente têm sido amplamente explorados na mecânica quântica,
inclusive em analogias com efeitos eletromagnéticos. No entanto, essas analogias entre as
forças inerciais sobre partículas massivas e as forças electromagnéticas sobre partículas carregadas
não é nenhuma novidade. Elas foram exploradas por Aharonov e Carmi em 1970 e por
Tsai e Neilson em 1988 no contexto de uma fase quântica rotacional similar à fase de Aharonov-
Bohm. Baseados nessa mesma analogia, Dattoli e Quattromini introduziram estados quânticos
de Coriolis análogos aos níveis de Landau. Em 1915, Barnett já havia publicado um artigo
sobre magnetização devido à rotação o qual teve recentemente um interesse renovado aplicado
a nanoestruturas. Um análogo rotacional do efeito Hall clássico foi proposto e os efeitos inerciais
da rotação foram estudados em spintrônica. Espectros de energia tipo níveis de Landau
aparecem sob a ação da força de Coriolis quando a força centrífuga agindo nos elétrons livres
é compensada por um campo elétrico radial. Neste trabalho, vamos demonstrar efeitos devido
à rotação e ao campo magnético em um disco condutor girante. Estudaremos as interações
eletromagnéticas e inerciais simultaneamente. Alguns valores para a relação entre o campo
magnético e a rotação serão escolhidos e resultarão em níveis tipo Landau para um sistema com
força resultante composta pelas forças de Coriolis e magnética. Um mesmo comportamento
para o espectro de energia será obtido sem força magnética compondo a força resultante.
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