Global ETD Search

1	Numerical modeling of low-pressure plasmas: applications to electric double layers Meige, Albert, albert@meige.net January 2006 (has links) Inductive plasmas are simulated by using a one-dimensional particle-in-cell simulation including Monte Carlo collision techniques (pic/mcc). To model inductive heating, a non-uniform radio-frequency (rf) electric field, perpendicular to the electron motion is included into the classical particle-in-cell scheme. The inductive plasma pic simulation is used to confirm recent experimental results that electric double layers can form in current-free plasmas. These results differ from previous experimental or simulation systems where the double layers are driven by a current or by imposed potential differences. The formation of a super-sonic ion beam, resulting from the ions accelerated through the potential drop of the double layer and predicted by the pic simulation is confirmed with nonperturbative laser-induced fluorescence measurements of ion flow. It is shown that at low pressure, where the electron mean free path is of the order of, or greater than the system length, the electron energy distribution function (eedf) is close to Maxwellian, except for its tail which is depleted at energies higher than the plasma potential. Evidence supporting that this depletion is mostly due to the high-energy electrons escaping to the walls is given. ¶ A new hybrid simulation scheme (particle ions and Boltzmann/particle electrons), accounting for non-Maxwellian eedf and self-consistently simulating low-pressure high-density plasmas at low computational cost is proposed. Results obtained with the improved hybrid model are in much better agreement with the full pic simulation than the classical non self-consistent hybrid model. This model is used to simulate electronegative plasmas and to provide evidence supporting the fact that propagating double layers may spontaneously form in electronegative plasmas. It is shown that critical parameters of the simulation were very much aligned with critical parameters of the experiment. plasma current-free double layer particle-in-cell simulation stochastic heating electronegative double layer model
2	Plasma cloud penetration across magnetic boundaries Hurtig, Tomas January 2004 (has links) No description available. Laboratory plasma experiments Particle in cell simulation Anomalous resistivity Fast magnetic field diffusion Anomalous particle transport
3	Plasma cloud penetration across magnetic boundaries Hurtig, Tomas January 2004 (has links) No description available. Laboratory plasma experiments Particle in cell simulation Anomalous resistivity Fast magnetic field diffusion Anomalous particle transport
4	Study of nonlinear structures and dynamics in collisionless plasmas created by the interaction between high power laser and cluster medium / 高強度レーザーとクラスター媒質との相互作用により生成する無衝突プラズマ中での非線形構造とダイナミクスに関する研究 Matsui, Ryutaro 25 March 2019 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第21888号 / エネ博第389号 / 新制\|\|エネ\|\|75(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻 / (主査)教授岸本泰明, 教授中村祐司, 教授田中仁 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DFAM High intensity laser-cluster interaction Particle-in-cell simulation Cluster medium Collisionless plasma boundary layer Collisionless shock acceleration 501
5	Understanding non-linear development of lower hybrid waves and ion acceleration driven by energetic ion injection through particle-in-cell simulation / 電磁粒子シミュレーションによる高速イオン注入に伴う低域混成波の非線形発展及びイオン加速の理解 Kotani, Tsubasa 23 March 2023 (has links) 京都大学 / 新制・課程博士 / 博士(理学) / 甲第24424号 / 理博第4923号 / 新制\|\|理\|\|1703(附属図書館) / 京都大学大学院理学研究科地球惑星科学専攻 / (主査)教授田口聡, 教授松岡彩子, 教授石岡圭一 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM lower hybrid wave ring-like energetic ions ion acceleration harmonic structure of lower hybrid waves particle-in-cell simulation 400
6	Equilibrium and dynamics of collisionless current sheets Harrison, Michael George January 2009 (has links) In this thesis examples of translationally invariant one-dimensional (1D) Vlasov-Maxwell (VM) equilibria are investigated. The 1D VM equilibrium equations are equivalent to the motion of a pseudoparticle in a conservative pseudopotential, with the pseudopotential being proportional to one of the diagonal components of the plasma pressure tensor. A necessary condition on the pseudopotential (plasma pressure) to allow for force-free 1D VM equilibria is formulated. It is shown that linear force-free 1D VM solutions correspond to the case where the pseudopotential is an attractive central potential. The pseudopotential for the force-free Harris sheet is found and a Fourier transform method is used to find the corresponding distribution function. The solution is extended to include a family of equilibria that describe the transition between the Harris sheet and the force-free Harris sheet. These equilibria are used in 2.5D particle-in-cell simulations of magnetic reconnection. The structure of the diffusion region is compared for simulations starting from anti-parallel magnetic field configurations with different strengths of guide field and self-consistent linear and non-linear force-free magnetic fields. It is shown that gradients of off-diagonal components of the electron pressure tensor are the dominant terms that give rise to the reconnection electric field. The typical scale length of the electron pressure tensor components in the weak guide field case is of the order of the electron bounce widths in a field reversal. In the strong guide field case the scale length reduces to the electron Larmor radius in the guide magnetic field. 530.44
7	Laser à rayons X ultra-compact Raman XFEL / Ultra-compact X-ray free electron laser Raman XFEL Hadj-Bachir, Mokrane 15 December 2016 (has links) L’obtention d’un Laser à Électrons Libres X (LEL-X) compact est un objectif majeur pour le développement des lasers. Plusieurs schémas prometteurs de LEL-X ont été proposés en utilisant à la fois l’accélération d’électrons dans les plasmas et des onduleurs optiques en régime Compton ou Compton inverse. Nous avons proposé un nouveau concept de LEL-X compact baptisé Raman XFEL, en combinant la physique des LEL en régime Compton, des lasers XUV conventionnels basés sur l’interaction laser plasma, et de l’optique non-linéaire. Nous étudions dans cette thèse les étapes préalables pour déclencher un effet laser à rayons X lors de l’interaction entre un paquet d’électrons libres relativistes et un réseau optique créé par l’interférence transverse de deux impulsions laser intenses. Dans cet objectif j’ai développé un code particulaire baptisé RELIC. Les études menées avec le code RELIC nous ont permis d’étudier la dynamique d’électrons relativistes et les processus d’injection du paquet d’électrons dans le réseau optique. Grâce à RELIC, nous avons distingué de nouveaux régimes d’interaction en fonction des paramètres du paquet d’électrons, ainsi que de la géométrie du réseau optique. Ces études ont été appliquées à l’amplification du rayonnement X et appuyées par des simulations PIC. RELIC a également permis de modéliser et d’analyser la première expérience réalisée en octobre 2015 sur l’installation laser ’Salle Jaune’ au Laboratoire d’Optique Appliquée (LOA). Cette première expérience a été une étape très importante pour la validation des modèles théoriques, et pour la réalisation future d’un laser à électrons libre X Raman. / The quest for a compact X-ray laser has long been a major objective of laser science. Several schemes using optical undulators are currently considered, in order to trigger the amplification of back scattered radiation, in Compton or inverse Compton regime. We have proposed a new concept of compact XFEL based on a combination between the physics of free electron lasers, of laser-plasma interactions, and of nonlinear optics. In this thesis, we study the necessary steps to trigger a X-ray laser during the interaction between a free relativistic electron bunch and an optical lattice created by the interference of two intense transverse laser pulses. For this purpose I developed a particular tracking code dubbed RELIC. RELIC allowed us to study the dynamics and injection process of a bunch of relativistic electrons into the optical lattice. Thanks to RELIC, we distinguished several interaction regimes depending on the relativistic electron bunch parameters, and on those of the optical lattice and its geometry. These studies are applied to the X ray amplification and supported by PIC simulations. RELIC also allowed us to model and analyze the first experiment conducted in october 2015 on the ”Salle Jaune” laser facility at LOA. This first experiment was very important to validate our theoretical models, and should prove to be an essential milestone for the development of a Raman X-ray free electron laser. Interaction laser-plasma relativiste Codes de simulation particulaire Accélération d’électrons Lasers Laser à Électrons Libres XFEL Synchrotrons Rayonnement bêtatron Rayonnements cohérents et incohérents Relativistic laser-plasma interaction Particle-in-cell simulation Electron acceleration Lasers Free Electron Laser XFEL Synchrotron Betatron radiation Coherent and non-coherent radiation

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