Global ETD Search

31	Kinetische Plasmaprozesse und Welle-Teilchen-Wechselwirkung von Ionen im schnellen Sonnenwind / Theoretische Untersuchung und Auswertung von Helios Beobachtungen / Kinetic plasma processes and wave-particle interactions of ions in the fast solar wind / Theoretical investigations and data analysis of Helios observations Heuer, Michael 23 September 2005 (has links) No description available. 520 Astronomie Mathematics and Computer Science Schneller Sonnenwind Welle-Teilchen-Wechselwirkung Mikroinstabilitäten quasi-lineare Diffusion Diffusionsplateaus fast solar wind wave-particle interaction microinstabilities quasi-linear diffusion diffusion plateaus 39.50 33.80 TG RO
32	Effects of inter particle friction on the meso-scale hydrodynamics of dense gas-solid fluidized flows / Efeitos da fricção inter-partículas na hidrodinâmica de meso-escala de escoamentos gás-sólido fluidizados densos Seyed Reza Amini Niaki 21 November 2018 (has links) Gas-solid fluidized bed reactors are widely applied in chemical and energy industries, and their design and scale-up are virtually empirical, extremely expensive and time consuming. This scenario has motivated the development of alternative theoretical tools, and two-fluid modeling, where gas and particulate are both treated as interpenetrating continuum phases, has appeared as a most promising approach. Owing to the large domains to be resolved in real-scale fluidized bed reactors, only filtered modeling approaches are feasible, and closure models become necessary to recover sub-grid effects that are filtered by the very coarse numerical grids that are imposed owing to computational limitations. Those closure models, which in hydrodynamic formulations account for filtered interphase momentum exchanges and filtered and residual stresses in the phases, can be derived from results of highly resolved simulations (HRS) performed over small size domains under refined numerical grids. One widely practiced approach consists of applying two-fluid modeling under micro-scale defined closures, generally known as microscopic two-fluid modeling. This approach includes microscopic closures for solid phase stresses derived from the kinetic theory of granular flows (KTGF), which accounts for kinetic-collisional effects only, and is adequate to dilute flows. Otherwise, the conventional KTGF does not account for interparticle friction effects, and its application to dense flow conditions is quite questionable. In this work a literature available modified version of KTGF is applied which also accounts for interparticle friction, and highly resolved simulations are performed for dense flow conditions in order to evaluate the effects of friction over relevant filtered parameters (namely effective drag coefficient, filtered and residual stresses). Ranges of domain average solid volume fractions and gas Reynolds numbers are considered (macro-scale conditions) embracing dense gas-solid fluidized flows from suspensions up to pneumatic transport. The MFIX open source code is used in all the simulations, which are performed over 2D periodical domains for a unique monodisperse particulate. The HRS results (i.e. meso-scale flow fields) are filtered over regions compatible with grid sizes in large scale simulations, and the relevant filtered parameters of concern are derived and classified by ranges of other filtered parameters taken as independent variables (filtered solid volume fraction, filtered slip velocity, and filtered kinetic energy of solid velocity fluctuations, which are referred to as markers). Results show that the relevant filtered parameters of concern are well correlated to all of those filtered markers, and also to all of the imposed macro-scale conditions. Otherwise, interparticle friction showed no significant effects over any filtered parameter. It is recognized that this issue clearly requires further investigation notably regarding the suitability of the markers that were assumed for classifying the filtered results. The current work is intended as a contribution for future developments of more accurate closure models for large scale simulations of gas-solid fluidized flows. / Reatores de leito fluidizado de escoamento gás-sólido são largamente utilizados nas indústrias química e de energia, e o seu projeto e escalonamento são virtualmente empíricos, extremamente caros e demorados. Este cenário tem motivado o desenvolvimento de ferramentas teóricas alternativas, e a modelagem de dois fluidos, onde gás e particulado são ambos tratados com fases contínuas interpenetrantes, tem surgido como uma aproximação muito promissora. Devido aos grandes domínios a serem resolvidos em reatores de leito fluidizado de escala real, apenas aproximações de modelagem filtradas são viáveis, e modelos de fechamento tornam-se necessários para recuperar efeitos sub-malha que são filtrados pelas malhas numéricas grosseiras que são impostas devido as limitações computacionais. Estes modelos de fechamento, que em formulações hidrodinâmicas respondem principalmente por trocas de momentum filtradas entre fases e tensões filtradas e residuais nas fases, podem ser obtidos de resultados de simulações altamente resolvidas (SAR) realizadas em domínios de dimensões reduzidas sob malhas numéricas refinadas. Uma aproximação largamente praticada consiste na aplicação de modelagem de dois fluidos sob fechamentos definidos na micro-escala, genericamente conhecida como modelagem microscópica de dois fluidos. Esta aproximação inclui fechamentos microscópicos para tensões da fase sólida obtidos da teoria cinética dos escoamentos granulares (TCEG), que considera apenas efeitos cinéticos-colisionais, e é adequada para escoamentos diluídos. Por outro lado, a TCEG convencional não leva em conta efeitos de fricção interpartículas, e sua aplicação para condições densas de escoamento é bastante questionável. Neste trabalho aplica-se uma versão modificada da TCEG disponível na literatura que também leva em conta fricção interpartículas, e simulações altamente resolvidas são realizadas para condições de escoamentos densos visando avaliar os efeitos da fricção sobre os parâmetros filtrados relevantes (coeficiente de arrasto efetivo, tensões filtradas e residuais). Considera-se faixas de frações volumétricas de sólido e números de Reynolds do gás médios no domínio (condições de macro-escala) abrangendo escoamentos gás-sólido fluidizados densos desde suspensões até transporte pneumático. O código aberto MFIX é utilizado em todas as simulações, que foram executadas sobre domínios periódicos 2D para um único particulado monodisperso. Os resultados das SAR (i.e., campos de escoamento de meso-escala) foram filtrados sobre regiões compatíveis com tamanhos de malha praticados em simulações de grandes escalas, e os parâmetros filtrados relevantes de interesse são calculados e classificados por faixas de outros parâmetros filtrados tomados como variáveis independentes (fração volumétrica de sólido filtrada, velocidade de deslizamento filtrada, e energia cinética das flutuações de velocidade da fase sólida filtrada, que são referidos como marcadores). Os resultados mostram que os parâmetros filtrados relevantes de interesse são bem correlacionados com todos os marcadores, e também com todas as condições de macro-escala impostas. Por outro lado, a fricção interpartículas não mostrou efeitos significativos sobre qualquer parâmetro filtrado. Reconhece-se que este aspecto claramente requer investigações adicionais, notadamente com respeito à adequação dos marcadores que foram considerados para classificação dos resultados filtrados. O trabalho corrente é posto como uma contribuição para o desenvolvimento futuro de modelos de fechamento mais acurados para simulações de grandes escalas de escoamentos gás-sólido fluidizados. Escoamento gás-sólido Fluidização Interações partícula-partícula Modelagem de dois fluidos Modelagem sub-malha Simulação altamente resolvida Fluidization Gas-solid flow Highly resolved simulation Particle-particle interaction Sub-grid modeling Two-fluid modeling
33	The Hydrodynamic Interaction of Two Small Freely-moving Particles in a Couette Flow of a Yield Stress Fluid Firouznia, Mohammadhossein January 2017 (has links) No description available. Mechanical Engineering Chemical Engineering Physics Engineering yield stress fluid Carbopol gel hydrodynamic interaction noncolloidal suspension suspension Particle Image velocimetry Particle Tracking Velocimetry rheology particle interaction Couette flow simple-shear flow shear thinning fluid Guar gum
34	Προσομοίωση ηλεκτρομαγνητικής συμπεριφοράς σε αντιδραστήρες αερίων χαμηλής πίεσης και ασθενούς ιονισμού Σφήκας, Σπυρίδων 19 April 2010 (has links) Οι πηγές πλάσματος επαγωγικής ζεύξης (Inductively Coupled Plasma Sources – ICP’s), παρέχουν πλάσμα υψηλής πυκνότητας ηλεκτρονίων σε χαμηλή πίεση και έχουν ευρεία εφαρμογή στη σύγχρονη βιομηχανία ημιαγωγών και την κατεργασία επιφανειών. Σε πολύ χαμηλές πιέσεις, (~mTorr), οι εκκενώσεις πλάσματος παρουσιάζουν ιδιαίτερη συμπεριφορά όσον αφορά τη διείσδυση του ηλεκτρομαγνητικού πεδίου και την αλληλεπίδραση κύματος-σωματιδίου: Η ανώμαλη επιδερμική διείσδυση (anomalous skin effect) και η συντονισμένη αλληλεπίδραση κύματος-σωματιδίου όταν υπερτίθεται στατικό μαγνητικό πεδίο (resonant wave-particle interaction) είναι δύο φαινόμενα τυπικά σε αυτές τις εκκενώσεις. Η κατανόηση και μαθηματική ανάλυση αυτών των ιδιαίτερα περίπλοκων φαινομένων, ώστε να προσομοιωθούν με ακρίβεια αλλά και χωρίς χρονοβόρες υπολογιστικά διαδικασίες οι πηγές πλάσματος επαγωγικής ζεύξης, αποτελεί μια σύγχρονη επιστημονική και υπολογιστική πρόκληση. Στα πλαίσια αυτά, στην παρούσα διατριβή τέθηκε ως στόχος η αξιοποίηση της υπάρχουσας επιστημονικής γνώσης στον τομέα της υπολογιστικής προσομοίωσης πλάσματος, για την ανάπτυξη ταχύτατων προσομοιώσεων των πηγών πλάσματος επαγωγικής ζεύξης, διασφαλίζοντας ταυτόχρονα την εξαγωγή έγκυρων συμπερασμάτων: Η προσέγγιση αυτή συνίσταται στη διατύπωση υπόθεσης (μοντέλου), τον έλεγχό της σε σχέση με υπάρχοντα δεδομένα και την επαναδιατύπωσή της μέχρις ότου το μοντέλο να κριθεί επαρκές. Αρχικά αναπτύχθηκε ένα ρευστοδυναμικό μοντέλο πλάσματος βασισμένο στην υπόθεση ψευδουδετερότητας και αμφιπολικής διάχυσης των φορέων φορτίου, προκειμένου να προσομοιωθεί η ενισχυμένης μαγνητικής διαπερατότητας πηγή επαγωγικής ζεύξης MaPE–ICP. Τα αποτελέσματα της προσομοίωσης συγκρίνονται με τα πειραματικά στοιχεία προηγούμενων ερευνητών για εκκενώσεις Αργού και εξετάζεται η ικανότητα του ρευστοδυναμικού μοντέλου να παρέχει μια στοιχειώδη ποσοτική περιγραφή πλάσματος επαγωγικής ζεύξης σε χαμηλή πίεση. Η αξιοπιστία του ρευστοδυναμικού μοντέλου εξελίσσεται περεταίρω, με την ενσωμάτωση μιας αποτελεσματικής αριθμητικής επίλυσης της κινητικής εξίσωσης Boltzmann για τα ηλεκτρόνια. Τα αποτελέσματα της υβριδικής προσομοίωσης για εκκένωση Αργού πίεσης 30 mTorr στον αντιδραστήρα MaPE–ICP συγκρίνονται τόσο με αντίστοιχα πειραματικά δεδομένα όσο και με τα προηγούμενα αποτελέσματα της ρευστοδυναμικής προσομοίωσης και εξετάζεται η βελτίωση της ποιοτικής συμφωνίας όσον αφορά την επίδραση των παραμέτρων με ιδιαίτερο ενδιαφέρον. Στη συνέχεια αναπτύχθηκε ένα ρευστοδυναμικό μοντέλο εκκενώσεων αίγλης τύπου ECWR (Electron Cyclotron Wave Resonance) βασισμένο σε προκαθορισμένες οριακές συνθήκες για το ηλεκτρομαγνητικό πεδίο. Προσομοιώθηκε ένα διάκενο με πλάσμα Αργού σε πίεση 15 mTorr (μονοδιάστατο μοντέλο) και τα αποτελέσματα ελέγχθηκαν έναντι αναλυτικής θεωρίας, πειραματικών δεδομένων και αποτελεσμάτων προσομοίωσης Particle In Cell/Monte Carlo (PIC/MC). Επιπρόσθετα, τα αποτελέσματα προσομοίωσης για μια εκκένωση Αργού σε πίεση 1 mTorr εντός κυλινδρικού αντιδραστήρα τύπου ECWR (δισδιάστατο μοντέλο), συγκρίνονται με τα αποτελέσματα προσομοίωσης και πειραματικά στοιχεία. Τέλος, το μοντέλο έχει επεκταθεί για να περιλάβει την διάδοση του πλάσματος που παράγεται από μια τυπική πηγή πλάσματος τύπου ECWR σε μια περιοχή διάχυσης. Τα αποτελέσματα για εκκένωση Αργού πίεσης 5 mTorr συγκρίνονται με τα αντίστοιχα αποτελέσματα ενός μοντέλου σφαιρικής διάχυσης πλάσματος και εν προκειμένω εξετάζεται η πλήρης επεκτασιμότητα του εισαχθέντος ρευστοδυναμικού μοντέλου ECWR σε διεργασίες πλάσματος. / Inductively Coupled Plasma Sources (ICP’s) are capable of producing high density-low pressure plasmas in a variety of applications for the semiconductor and material processing industry. In the mTorr range, ICP discharges exhibit an extraordinary behaviour concerning the electromagnetic field propagation and wave-particle interaction: Anomalous skin effect and resonant wave-particle interaction within a superimposed static magnetic field consist two of the most typical phenomena. The efficient comprehension and mathematical description of such a complex gas discharge in order to fast and accurately simulate ICP sources, is still a challenging task. Within this context, the thesis focuses on evaluating the existing scientific knowledge in plasma computational modeling in order to develop not only rapidly converging but reliable ICP simulations: The implementation methodology consists on formulating an hypothesis (model) and repetitively inquiring its accuracy by checking the simulation results against existing experimental and/or other simulation data. The continuation of the model re-formulation process depends on the accuracy of the simulation results. Initally a simulation of a Magnetic Pole Enhanced (MaPE)-ICP plasma source was developed, under the assumptions of plasma quasineutrality and ambipolar diffusion. The simulation results were checked against the experimental data of previous workers for Argon discharges and the ability of the model to provide an elementary quantitative description of low pressure ICP sources was scrutinized. The validity of the fluid model was enhanced with the incorporation of a time effective numerical solution of the Boltzmann transport equation for electrons. Simulation results of the hybrid model were compared to the previous fluid simulation results and existing experimental data, for a 30 mTorr Argon discharge in the MaPE–ICP reactor. The major improvements of the qualitative agreement in regard to the effect of parameters with particular interest are discussed. Moreover, a fluid model of ECWR (Electron Cyclotron Wave Resonance) discharges, based on predefined boundary conditions for the electromagnetic field, was developed: The simulation results for a 15 mTorr Argon plasma within a slab (1-dimensional model) were checked against the particle in cell/Monte Carlo (PIC/MC) simulation results that can be found in the literature and also compared to the analytical theory and experimental data. In addition, the model was further developed to simulate realistic geometries as a cylindrical ECWR reactor (2-D) and the data were also compared to both simulation results and experimental data of other researchers. Finally, the model was extended in order to simulate plasma propagation from a typical ECWR plasma source to a diffusion region. The simulation results for an Argon plasma generated from a cylindrical ECWR source in a processing chamber at 5 mTorr were presented in order to verify the feasibility of model application in ECWR plasma processes. Υβριδικό μοντέλο Πλάσμα Εκκένωση αερίου Πηγές πλάσματος Αυτάρκες μοντέλο Διάδοση πλάσματος Εξίσωση Boltzmann Αριθμητική επίλυση 530.44 Numerical simulation Fluid model Hybrid model Plasma Inductively coupled plasma Cyclotron resonance Anomalous skin effect Wave-particle interaction Gas discharge Plasma sources Electromagnetic field Self-consistent model Plasma expansion Boltzmann equation
35	Relations de dispersion dans les plasmas magnétisés / Dispersion relations in magnetized plasmas Fontaine, Adrien 04 July 2017 (has links) Cette thèse décrit comment les ondes électromagnétiques se propagent dans les plasmas magnétisés, lorsque les fréquences sollicitées sont proches de la fréquence électron cyclotron. Elle porte sur l’analyse mathématique des variétés caractéristiques qui sont associées à des systèmes de type Vlasov-Maxwell relativiste avec paramètres rapides.La première partie s’intéresse aux plasmas froids des magnétosphères planétaires. On explique comment obtenir les relations de dispersion dans le cas d’un dipôle magnétique. Cela conduit à l’étude détaillée de certaines variétés algébriques de l’espace cotangent : les cônes et les sphères dits ordinaires et extraordinaires. La description géométrique de ces cônes et de ces sphères donne accès à une classification complète des ondes électromagnétiques susceptibles de se propager. Diverses applications sont proposées, concernant l’équation eikonale et l’absence de propagation en mode parallèle, ou encore concernant la structure des ondes dites en mode siffleur.La seconde partie porte sur la modélisation des plasmas chauds, typiquement ceux qui sont mis en jeu dans les tokamaks. On prouve dans un contexte réaliste que la propagation des ondes électromagnétiques s’effectue au travers d’un tenseur dielectrique. Ce tenseur est obtenu via une analyse fine des résonances cinétiques qui sont issues des interactions entre les particules (Vlasov) et les ondes (Maxwell). Il s’exprime comme une somme infinie d’intégrales singulières, faisant intervenir l’opérateur de Hilbert. Le sens mathématique de la formule donnant accès à ce tenseur est rigoureusement justifié. / This thesis describes how electromagnetic waves propagate in magnetized plasmas, when the frequencies are in a range around the electron cyclotron frequency. It focuses on the mathematical analysis of the characteristic varieties which are associated with relativistic Vlasov-Maxwell systems involving fast parameters. The first part is concerned with cold plasmas issued from planetary magnetospheres. We explain how to obtain the dispersion relations in the case where the magnetic field is given by a dipole model. This leads to the detailed study of some algebraic varieties from the cotangent space: the so-called ordinary and extraordinary cones and spheres. The geometrical description of these cones and spheres gives access to a complete classification of the electromagnetic waves which can propagate. Various applications are proposed, concerning the eikonal equation and the absence of purely parallel propagation, or concerning the structure of whistler waves. The second part focuses on the modelling of hot plasmas, typically like those involved in tokamaks. We prove in a realistic context that the propagation of electromagnetic waves is governed by some dielectric tensor. This tensor is obtain via some careful analysis of the kinetic resonances, which are issued from the interactions between the particles (Vlasov) and the waves (Maxwell). It can be expressed as an infinite sum of singular integrals, involving the Hilbert transform. The mathematical meaning of the formula defining this tensor is rigorously justified. Equations de Vlasov-Maxwell relativistes Plasmas froids magnétisés Propagation d'ondes électromagnétiques Relations de dispersion Variété caractéristique Equation eikonal Equation de Appleton-Hartree Résonances cinétiques Tenseur diélectrique Transformée de Hilbert Relativistic Vlasov-Maxwell equations Cold magnetized plasmas Electromagnetic wave propagation Dispersion relations Characteristic variety Appleton-Hartree equations Eikonal equations Hot magnetized plasmas Wave particle interaction Kinetic resonances Dielectric tensor Hilbert transform

Page generated in 0.4304 seconds