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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Relativistic Self-Focusing, Magnetic Field Generation and Particle Acceleration in Underdense Plasmas

Naseri, Neda 11 1900 (has links)
In this thesis the following problems are studied: 1-Relativistic self-focusing and channelling of intense laser pulses have been studied in underdense plasma using 2D PIC simulations, for different laser powers and plasma densities. Analytical solutions for the stationary evacuated channels have been recovered in PIC simulations. It is shown that otherwise stable channels can accelerate electrons due to surface waves on the walls of the channels. Relativistic filaments with finite electron density are unstable to transverse modulations which lead in the nonlinear stage to the break-up of laser pulses into independent filaments. 2-Although 3D simulations are limited, they are more realistic. Azimuthal stability of the laser pulses in interaction with underdense plasma can only be studied in 3D geometry. Relativistic self-focusing and channelling of intense laser pulses have been studied in underdense plasma using 3D PIC simulations, for different laser powers and plasma densities. Analytical solutions for the stationary evacuated channels and ring structure have been recovered in PIC simulations. The stability of ring structure due to azimuthal perturbations has been studied both in theory and in simulations. The gain length of such instability is smaller at higher densities $(>0.1n_{cr})$. It is shown that the azimuthal perturbation can break up the azimuthal symmetry of the laser pulse. 3-Working with circularly polarized laser pulses, gave us a motivation to study Inverse Faraday Effect in interaction of circularly polarized laser pulses with plasma. Axial magnetic field generation by intense circularly polarized laser beams in underdense plasmas has been studied with 3D particle-in-cell (PIC) simulations and by means of theoretical analysis. The source of azimuthal nonlinear currents and of the axial magnetic field depends on the transverse inhomogeneities of the electron density and laser intensity. The fields reach maximum strength of several tens of MG for laser pulses undergoing relativistic self-focusing and channelling in moderately relativistic regime. 4-Electron wakefield acceleration was studied in support of the experiment which was carried on using 7 TW laser beam at Canadian Advanced Laser Light source facility. 2D simulations were performed to study this problem. The energy the electrons gained in the process was peaked at 20-30 Mev close to the experimental results.
2

Relativistic Self-Focusing, Magnetic Field Generation and Particle Acceleration in Underdense Plasmas

Naseri, Neda Unknown Date
No description available.
3

Zum Dynamoeffekt in extern getriebenen Strömungen

Gellert, Marcus January 2004 (has links)
Die Frage nach der Herkunft und der dynamischen Entwicklung langlebiger kosmischer Magnetfelder ist in vielen Details noch unbeantwortet. Es besteht zwar kein Zweifel daran, dass das Magnetfeld der Erde und anderer kosmischer Objekte durch den sogenannten Dynamoeffekt verursacht werden, der genaue Mechanismus als auch die notwendigen Voraussetzungen und Randbedingungen der zugrundeliegenden Strömungen sind aber weitgehend unbekannt. Die für einen Dynamo interessanten Strömungsmuster, die im Inneren von Himmelskörpern durch Konvektion und differentielle Rotation entstehen, sind Konvektionsrollen parallel zur Rotationsachse. Auf einer Strömung mit eben solcher Geometrie, der sogenannten Roberts-Strömung, basieren die in der vorliegenden Arbeit untersuchten Dynamomodelle. Mit Methoden der nichtlinearen Dynamik wird versucht, das Systemverhalten bei Änderung der Systemparamter genauer zu charakterisieren. Die numerischen Untersuchungen beginnen mit einer Analyse der Dynamoaktivität der Roberts-Strömung in Abhängigkeit von den zwei freien Parametern in den Modellgleichungen, der magnetischen Prandtl-Zahl und der Stärke des Energieinputs. Gefunden werden verschiedene Lösungstypen die von einem stationären Magnetfeld über periodische bis zu chaotischen Zuständen reichen. Die yugrundeliegenden Symmetrien werden beschrieben und die Bifurkationen, die zum Wechsel der Lösungstypen führen, charakterisiert. Zusätzlich gibt es Bereiche bei sehr kleinen Prandtl-Zahlen, in denen überhaupt kein Dynamo existiert. Dieses Verhalten wird in der Literatur auch für viele andere numerisch ausgewertete Modelle beschrieben. Im Übergangsbereich zwischen dynamoaktivem und dynamoinaktivem Bereich wird das Auftreten einer sogenannten Blowout-Bifurkation gefunden. Desweiteren beschäftigt sich die Arbeit mit der Frage, inwiefern Helizität, also eine schraubenförmige Bewegung, der Strömung den Dynamoeffekt beeinflusst. Dazu werden ähnliche Strömungstypen verglichen, die sich hauptsächlich in ihrem Helizitätswert unterscheiden. Es wird gefunden, dass ein bestimmter Wert der Helizität nicht unterschritten werden darf, um einen stabilen Roberts-Dynamo zu erhalten. / The question of origin and development of longlasting cosmic magnetic fields is in many details an unanswered question. There is no doubt that the magnetic fields of cosmic objects like the earth, the sun and larger structures are caused by the so called dynamo effect. The exact mechanism as well as the necassary properties and boundary conditions for the underlying flow field are mostly unknown. The flow pattern believed to act as the source of dynamo activity in the inner of cosmic bodies are convection-like rolls parallel to the rotation axis of this objects and are results of the acting body forces due to differential rotation and thermal convection. The basis of the considered dynamo model is a flow field revealing such flow structures, the so called Roberts flow. The numerical investigations start with an analysis of dynamo activity of the Roberts flow in dependence on the two free parameters magnetic Prandtl number and forcing strength. The model shows different types of solutions starting from steady magnetic states in a very small parameter region at larger magnetic Prandtl numbers, time-periodic solutions and chaotic behavior for stronger forcing. For small magnetic Prandtl numbers the system doesn't carry any magnetic field. This 'small Prandtl number problem' is in accordance with the behavior of several other numerically investigated dynamo models described in the literature. The transient region between dynamo activity and the non-magnetic states can be classified by a so-called blowout bifurcation. Furthermore the investigation deals with the question in what way the helical structure of the flow field indicated by a non-vanishing kinetic helicity influences the dynamo process. The comparison of very similar flow families, mainly distinguishable by their different helicity values, leads to the result that beneath a lower bound no stable Roberts dynamo is working.
4

Modèle Vlasov-Maxwell pour l'étude des instabilités de type Weibel / Vlasov Maxwell model for the study of Weibel type instabilities

Inglebert, Aurélie 19 November 2012 (has links)
L'origine de champs magnétiques observés dans les plasmas de laboratoire et d'astrophysique est l'un des problèmes récurrents en physique des plasmas. À cet égard, les instabilités de type Weibel sont considérées d'une grande importance. Ces instabilités ont pour origine une anisotropie de température (instabilité de Weibel) et des moments des électrons (instabilité de filamentation de courant). L'objectif principal de cette thèse est l'étude théorique et numérique de ces instabilités dans un plasma non collisionnel en régime relativiste. Le premier aspect de ce travail est l'étude du régime non-linéaire de ces instabilités et du rôle des effets cinétiques et relativistes sur la structure des champs électromagnétiques auto-cohérents. Dans ce cadre, un problème essentiel pour les applications et la théorie, concerne l'identification et l'analyse des structures cohérentes développées spontanément dans le régime non-linéaire sur des échelles cinétiques. Un deuxième aspect du travail est le développement de techniques analytiques et numériques pour l'étude des plasmas non collisionnels. Le modèle mathématique de référence, à la base des études des plasmas chauds, est le modèle Vlasov-Maxwell, où l'équation de Vlasov (théorie des champs moyens) est couplée aux équations de Maxwell de façon auto-cohérente. Un modèle unidimensionnel, le modèle multi-faisceaux, a également été introduit durant cette thèse. Basé sur une technique de réduction en dimension, il est à la fois un modèle analytique "simple" présentant l'avantage de pouvoir résoudre une équation de Vlasov 1D pour chaque faisceau de particules, et un modèle numérique moins coûteux qu'un modèle complet / The origin of magnetic fields observed in laboratory and astrophysical plasmas is one ofthe most challenging problems in plasma physics. In this respect, the Weibel type instabilities are considered of key importance. These instabilities are caused by a temperature anisotropy (Weibel instability) and electron momentum (current filamentation instability). The main objective of this thesis is the theoretical and numerical study of these instabilities in a collisionless plasma in the relativistic regime. The first aspect of this work is to study the nonlinear regime of these instabilities and the role of kinetic and relativistic effects on the structure of self-consistent electromagnetic fields. In this context, a key problem for the theory and applications, is the identification and analysis of coherent structures developed spontaneously in the nonlinear regime of kinetic scales. A second aspect of the work is the development of analytical and numerical techniques for the study of collisionless plasmas. A mathematical model of reference is the Vlasov-Maxwell model, where the Vlasov equation (mean field theory) is coupled to the Maxwell equations in a self-consistent way. A one-dimensional model, the multi-stream model, is also introduced. Based on a dimensional reduction technique, it is both an analytical model "simple" having the advantage of being able to solve a 1D Vlasov equation for each particle beam, and a numerical model less expensive than a complete model

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