Global ETD Search

111	Space Plasma Dynamics : Instabilities, Coherent Vortices and Covariant Parametrization Sundkvist, David January 2005 (has links) <p>The magnetospheric cusps are two funnel-like regions of Earth's magnetosphere where solar wind plasma can have direct access to the ionosphere. The cusps are very dynamic regions where wave-particle interactions continuously take place and redistribute energy among different particle populations. In this thesis, both low and high frequency plasma waves in the cusp have been studied in detail using data from the Cluster spacecraft mission. The waves were studied with respect to frequency, Poynting flux and polarization. Wavelengths have also been estimated using multi-spacecraft techniques. At low frequencies, kinetic Alfvén waves and nonpotential ion cyclotron waves are identified and at high frequencies, electron cyclotron waves, whistler waves, upper-hybrid and RX-waves are observed. A common generation mechanism called the shell-instability is proposed for several of the wave modes present in the cusp, both at low and high frequencies. </p><p>The plasma in the cusp is shown to be strongly inhomogeneous. In an inhomogeneous low-frequency magnetoplasma, kinetic Alfvén waves couple to drift-waves. Such drift-kinetic Alfvén waves have long been believed to nonlinearly self-interact and form coherent structures in the form of drift-kinetic Alfvén vortices. In this thesis the first unambiguous direct measurements confirming the existence of such vortices in a turbulent space plasma are presented. Some of the crucial parameters such as the vortex radius are determined. </p><p>Plasma theory is electrodynamics applied to a large collection of charged particles. In this thesis a new way of looking at the fundamental Maxwell tensor is presented. A covariant spectral density tensor containing information on electromagnetic waves is formed. This tensor is then decomposed into irreducible components by using the spinor formalism for an arbitrary metric. The obtained fundamental tensors are shown to correspond both to well known tensors in Maxwell's theory, as well as several physically interesting new tensors.</p> Space and plasma physics space physics plasma instabilities turbulence coherent structures vortex self-organization magnetosphere waves electromagnetism covariant space instrumentation Rymd- och plasmafysik Space physics Rymdfysik
112	Space Plasma Dynamics : Instabilities, Coherent Vortices and Covariant Parametrization Sundkvist, David January 2005 (has links) The magnetospheric cusps are two funnel-like regions of Earth's magnetosphere where solar wind plasma can have direct access to the ionosphere. The cusps are very dynamic regions where wave-particle interactions continuously take place and redistribute energy among different particle populations. In this thesis, both low and high frequency plasma waves in the cusp have been studied in detail using data from the Cluster spacecraft mission. The waves were studied with respect to frequency, Poynting flux and polarization. Wavelengths have also been estimated using multi-spacecraft techniques. At low frequencies, kinetic Alfvén waves and nonpotential ion cyclotron waves are identified and at high frequencies, electron cyclotron waves, whistler waves, upper-hybrid and RX-waves are observed. A common generation mechanism called the shell-instability is proposed for several of the wave modes present in the cusp, both at low and high frequencies. The plasma in the cusp is shown to be strongly inhomogeneous. In an inhomogeneous low-frequency magnetoplasma, kinetic Alfvén waves couple to drift-waves. Such drift-kinetic Alfvén waves have long been believed to nonlinearly self-interact and form coherent structures in the form of drift-kinetic Alfvén vortices. In this thesis the first unambiguous direct measurements confirming the existence of such vortices in a turbulent space plasma are presented. Some of the crucial parameters such as the vortex radius are determined. Plasma theory is electrodynamics applied to a large collection of charged particles. In this thesis a new way of looking at the fundamental Maxwell tensor is presented. A covariant spectral density tensor containing information on electromagnetic waves is formed. This tensor is then decomposed into irreducible components by using the spinor formalism for an arbitrary metric. The obtained fundamental tensors are shown to correspond both to well known tensors in Maxwell's theory, as well as several physically interesting new tensors. Space and plasma physics space physics plasma instabilities turbulence coherent structures vortex self-organization magnetosphere waves electromagnetism covariant space instrumentation Rymd- och plasmafysik Space physics Rymdfysik
113	Instrumentation for energetic Neutral atom measurements at Mars, Venus and The Earth Brinkfeldt, Klas January 2005 (has links) This thesis deals with the development and calibrations of sensors to measure energetic neutral atoms (ENAs) at Mars, Venus, and the Earth. ENAs are formed in charge exchange processes between energetic, singly--charged ions and a cold neutral gas. Since ENAs can travel in long straight trajectories, unaffected by electric or magnetic fields, they can be used to remotely image plasma interactions with neutral atmospheres. ENA instrument techniques have matured over the last decade and ENA images of the Earth's ring current for example, have successfully been analyzed to extract ion distributions and characterize plasma flows and currents in the inner magnetosphere. Three different ENA sensors have been developed to image ENAs at Mars, Venus, and the Earth. Two of them, the nearly identical Neutral Particle imagers (NPIs) are on-board the Mars Express and Venus Express spacecraft as a part of the Analyzer of Space Plasmas and Energetic Atoms (ASPERA-3 and 4) instruments. The third is the Neutral Atom Detector Unit, NUADU, aboard the TC-2 spacecraft of the Double Star mission. The NPI design is based on a surface reflection technique to measure low energy (~0.3-60 keV) ENAs, while the NUADU instrument is based on a simple design with large geometrical factor and solid state detectors to measure high energy ENAs (~20-300 keV). The calibration approach of both NPI sensors were to define the detailed response, including properties such as the angular response function and efficiency of one reference sensor direction then find the relative response of the other sensor directions. Because of the simple geometry of the NUADU instrument, the calibration strategy involved simulations to find the cutoff energy, geometrical factor and angular response. The NUADU sensor head was then calibrated to find the response to particles of different mass and energy. The NPI sensor for the Mars Express mission revealed a so-called priority effect in the sensor that lowers the angular resolution at high detector bias. During the calibration of the Venus Express NPI sensor tests were made which showed that the priority effect is a result of low amplitude (noise) pulses generated in the detector system. The conclusion is that the effect is caused by capacitive couplings between different anode sectors of the sensor. The thresholds on the preamplifiers were set higher on the Venus Express NPI, which removed the priority effect. Two of the three ENA experiments, the Double Star NUADU instrument and the Mars Express NPI sensor, have successfully measured ENAs that are briefly described in the thesis. The first ENA measurements at Mars were performed with Mars Express. Initial results from the NPI include measurements of ENAs formed in the Martian magnetosheath and solar wind ENAs penetrating to the nightside of Mars. The first results from NUADU in Earth orbit show the expected ENA emissions from a storm time ring current. Also, together with the HENA instrument on the IMAGE spacecraft, NUADU have produced the first multi-point ENA image of the ring current. Energetic neutral atoms instruments and techniques mass spectrometry microchannel plates solid state detectors solar wind interaction planets magnetosphere exosphere ring current Space physics Rymdfysik
114	DYNAMIQUE DES STRUCTURES COHERENTES MAGNETIQUES A L'ECHELLE IONIQUE ET COUPLAGE AVEC LES ONDES DE SIFFLEMENT PENDANT LES SOUS-ORAGES. Tenerani, Anna 26 October 2012 (has links) (PDF) Dans cette thèse, on propose un nouveau modèle de couplage auto-cohérent entre des structures magnétiques cohérentes sur les échelles ioniques et des ondes dites de sifflement (whistlers, en anglais) à plus hautes fréquences, afin d'interpréter les données expérimentales recueillies par les satellites Cluster pendant un sous-orage magnétique dans la région nocturne de la magnétosphère terrestre. Le couplage fournit un mécanisme pour confiner et transporter les ondes whistlers par l'intermédiaire d' une onde nonlinéaire qui se propage obliquement par rapport au champ magnétique. Cette étude s'appuie sur une analyse des données expérimentales, sur une modélisation théorique ainsi que sur des simulations numériques. Pendant les sous-orages magnétiques, la magnétosphère est soumise à de fortes perturbations magnétiques et électriques dans une vaste gamme de fréquences, qui vont des basses fréquences, inférieures ou de l'ordre de l'échelle temporelle typique ionique, aux hautes fréquences, supérieures ou de l'ordre de l' échelle temporelle typique électronique. Afin de connaître les processus physiques qui déterminent la dynamique de la magnétosphère pendant les sous-orages, il est fondamental de comprendre si, et avec quel méchanisme, des couplages peuvent se produire entre des ondes qui se propagent sur des temps caractéristiques différents. Des structures magnétiques à basse fréquence ont déjá été obsérvées dans des régions comme la magnétogaine et le vent solaire, éventuellement associées à des ondes whistlers à plus haute fréquence. Dans cette thèse, on montre que des structures similaires sont obsérvées dans la couche de plasma à l'intérieur de la magnétosphère. On s'intérroge ensuite sur la façon dont l'inhomogénéité de telles structures peut influencer la propagation des ondes à plus haute fréquence. Grâce à ses quatre satellites en configuration tetraédrique et à ses mésures à haute résolution temporelle, la mission Cluster nous offre une occasion unique de pouvoir analyser la structure spatiale des perturbations stationnaires (ou se propageant) et d'étudier la dynamique du plasma sur des échelles temporelles plus courtes, telles que celles des ondes whistlers. Ainsi, je décrirai les émissions d'ondes whistlers détectées par les satellites Cluster à l'intérieur de structures magnétiques cohérentes situées dans un écoulement de plasma rapide pendant le sous-orage du 17 Août 2003. Au cours de cette période, les satellites Cluster sont situés dans la couche de plasma, séparés d'une distance de l'ordre des échelles spatiales typiques ioniques (le rayon de giration ou la longueur d'inertie des ions). Les ondes whistlers sont corrélées avec des structures magnétiques characterisées par un minimum du module du champ magnétique et un maximum de densité du plasma. Ces dernières ont été modélisées comme des ondes planes nonlinéaires de type lent qui piègent et transportent les ondes whistlers. A partir d'une étude théorique et numérique en utilisant une approche bi-fluide, on peut alors reproduire les données observationnelles. Le rôle possible de telles structures couplées dans la physique des sous-orages est aussi discuté. Ce nouveau mécanisme de piégeage, étudié ici en utilisant comme guide pour les whistlers une onde oblique de type magnétosonique, est d'intérêt plus général par rapport au contexte spécifique des observations présentées dans cette thèse. En effet, d'autres ondes nonlinéaires, comme par exemple les ondes d' Alfvén obliques ou d' Alfvén cinétiques dans les plasmas à beta fort (où beta est le rapport de la pression thermique du plasma sur la pression magnétique), pourraient aussi transporter les whistlers. Ce modèle de piégeage constitue aussi une explication alternative aux modèles existants qui considèrent une inhomogénéité stationnaire sous la forme d'un canal de densité. Enfin, l'étude décrite dans cette thèse concerne des problématiques fondamentales en physique des plasmas, comme la propagation d'ondes dans les milieux inhomogènes et l'interaction entre modes sur des échelles temporelles différentes. PHYSIQUE DES PLASMAS PHYSIQUE DE LA MAGNETOSPHERE ONDES NON LINEAIRES ONDES DE SIFFLEMENTS SOUS-ORAGES MAGNETIQUES TWO-FLUID NUMERICAL SIMULATIONS ANALYSE DE DONNEES DES SATELLITES
115	Effects of ionospheric conductance in high-latitude phenomena Benkevitch, Leonid V 09 February 2006 In this thesis, the relationship between several high-latitude phenomena and the ionospheric conductance in both hemispheres is studied theoretically and experimentally. </p>Theoretically, the high-latitude electrodynamics is studied by considering currents in the magnetosphere-ionosphere system resulting from the ionospheric sheet current redistribution between the conjugate ionospheres. It is shown that strong flow between the conjugate ionospheres, the interhemispheric currents (IHC), can be set up if the conductance distribution is asymmetric in the conjugate ionospheric regions. Such conditions are typical for solstices owing to the differences in the solar illumination. Analytical and numerical modeling shows that IHCs can appear in the regions of strong conductance gradient, more specifically around the solar terminator line, and that the intensity of the IHCs can be comparable to the intensity of the well known Region 1/Region 2 currents. The effect of IHC excitation on observable magnetic perturbations on the ground is investigated. It is shown that in the vicinity of the solar terminator line, the pattern of magnetic perturbation can be such that an apparent equivalent current vortex can be detected. In addition, strong conductance gradients are shown to affect significantly the quality of the ionospheric plasma flow estimates from the ground-based magnetometer data. </p>Experimentally, the effect of the nightside ionospheric conductance on occurrence of substorms, global storm sudden commencement and radar auroras is investigated. To characterize substorm occurrence, new parameters, the derivatives of the classical AE and AO indices, are introduced. It is shown that the seasonal and diurnal variations of these parameters are controlled by the total nightside ionospheric conductance in the conjugate regions. The substorm onsets preferentially occur at low levels of the total conductance, which is consistent with the idea of the substorm triggering through the magnetosphere-ionosphere feedback instability. It is hypothesized that the total conductance affects the global storm onsets as well. To check this idea, the 33-year sudden storm commencement (SSC) data are considered. The semiannual, annual, semidiurnal, and diurnal variations in the SSC occurrence rate are found to be significant and these components exhibit a strong relationship with the total conductance of the high-latitude ionospheres. Finally, the SuperDARN midnight echo occurrence is shown to correlate, for some radars, with the total conductance minima and presumably with electric field maxima, which is consistent with general expectation that the F-region irregularities occur preferentially during times of enhanced electric fields. The gradients of the high-latitude conductance can also lead to significant errors in the plasma convection estimates from the ground-based magnetometers, and to investigate this effect a statistical assessment of the difference between the true plasma convection (SuperDARN) and the magnetometer-inferred equivalent convection direction is performed. The largest differences are found for the transition region between the dark and sunlit ionospheres and in the midnight sector where strong conductance gradients are expected due to particle precipitation. Consideration of regular conductance gradients due to solar illumination improves the agreement between the radar and magnetometer data. Finally, an attempt is made to demonstrate the effects of conductance upon the properties of traveling convection vortices (TCVs). Joint SuperDARN and magnetometer data reveal that there is resemblance between the magnetometer and radar inferred TCV images on a scale of thousands of kilometers. However, on a smaller scale of hundreds of kilometers, significant differences are observed. potential ionospheric conductance PDE geomagnetic activity substorm SSC echo occurrence 3-D current numerical distribution model convection magnetosphere ionosphere TCV FAC IHC interhemispheric magnetometer radar SuperDARN complex analysis
116	Effects of ionospheric conductance in high-latitude phenomena Benkevitch, Leonid V 09 February 2006 (has links) In this thesis, the relationship between several high-latitude phenomena and the ionospheric conductance in both hemispheres is studied theoretically and experimentally. </p>Theoretically, the high-latitude electrodynamics is studied by considering currents in the magnetosphere-ionosphere system resulting from the ionospheric sheet current redistribution between the conjugate ionospheres. It is shown that strong flow between the conjugate ionospheres, the interhemispheric currents (IHC), can be set up if the conductance distribution is asymmetric in the conjugate ionospheric regions. Such conditions are typical for solstices owing to the differences in the solar illumination. Analytical and numerical modeling shows that IHCs can appear in the regions of strong conductance gradient, more specifically around the solar terminator line, and that the intensity of the IHCs can be comparable to the intensity of the well known Region 1/Region 2 currents. The effect of IHC excitation on observable magnetic perturbations on the ground is investigated. It is shown that in the vicinity of the solar terminator line, the pattern of magnetic perturbation can be such that an apparent equivalent current vortex can be detected. In addition, strong conductance gradients are shown to affect significantly the quality of the ionospheric plasma flow estimates from the ground-based magnetometer data. </p>Experimentally, the effect of the nightside ionospheric conductance on occurrence of substorms, global storm sudden commencement and radar auroras is investigated. To characterize substorm occurrence, new parameters, the derivatives of the classical AE and AO indices, are introduced. It is shown that the seasonal and diurnal variations of these parameters are controlled by the total nightside ionospheric conductance in the conjugate regions. The substorm onsets preferentially occur at low levels of the total conductance, which is consistent with the idea of the substorm triggering through the magnetosphere-ionosphere feedback instability. It is hypothesized that the total conductance affects the global storm onsets as well. To check this idea, the 33-year sudden storm commencement (SSC) data are considered. The semiannual, annual, semidiurnal, and diurnal variations in the SSC occurrence rate are found to be significant and these components exhibit a strong relationship with the total conductance of the high-latitude ionospheres. Finally, the SuperDARN midnight echo occurrence is shown to correlate, for some radars, with the total conductance minima and presumably with electric field maxima, which is consistent with general expectation that the F-region irregularities occur preferentially during times of enhanced electric fields. The gradients of the high-latitude conductance can also lead to significant errors in the plasma convection estimates from the ground-based magnetometers, and to investigate this effect a statistical assessment of the difference between the true plasma convection (SuperDARN) and the magnetometer-inferred equivalent convection direction is performed. The largest differences are found for the transition region between the dark and sunlit ionospheres and in the midnight sector where strong conductance gradients are expected due to particle precipitation. Consideration of regular conductance gradients due to solar illumination improves the agreement between the radar and magnetometer data. Finally, an attempt is made to demonstrate the effects of conductance upon the properties of traveling convection vortices (TCVs). Joint SuperDARN and magnetometer data reveal that there is resemblance between the magnetometer and radar inferred TCV images on a scale of thousands of kilometers. However, on a smaller scale of hundreds of kilometers, significant differences are observed. potential ionospheric conductance PDE geomagnetic activity substorm SSC echo occurrence 3-D current numerical distribution model convection magnetosphere ionosphere TCV FAC IHC interhemispheric magnetometer radar SuperDARN complex analysis
117	Etude de l'interactionentre le vent solaire et la magnetosphere de la Terre: Modele theorique et Application sur l'analyse de donnees de l'evenement du Halloween d'octobre 2003 Baraka, Suleiman 21 March 2007 (has links) (PDF) Une nouvelle approche, en utilisant un 3D code électromagnétique (PIC), est présentée pour étudier la sensibilité de la magnétosphère de la terre à la variabilité du vent solaire. Commençant par un vent solaire empiétant sur une terre magnétisée, le temps a été laissé au système ainsi une structure d'état d'équilibre de la magnétosphère a été atteinte. Une perturbation impulsive a été appliquée au système par changeant la vitesse du vent solaire pour simuler une dépression en sa pression dynamique, pour zéro, au sud et du nord du champ magnétique interplanétaire(IMF). La perturbation appliquée, un effet de trou d'air qui pourrait être décrit comme espace ~15Re est formé pour tous les cas d'état de IMF. Dès que le trou d'air a frappé le choc d'arc initial de la magnétosphère régulière, une reconnexion entre le champ magnétique de la terre et le IMF sud a été notée à la coté jour magnétopause(MP). Pendant la phase d'expansion du système, la frontière externe de la coté jour du MP a enfoncé quand IMF=0, et pourtant elle sa forme de balle quand un IMF au sud et nordique étaient inclus. La relaxation de temps du MP pour les trois cas de IMF a été étudiée. Le code est alors appliqué pour étudier l'événement d'Halloween de l'octobre 2003. Notre simulation a produit un nouveau genre de trou d'air, un espace raréfié qui a été produit après un gradient fort en IMF d'empiétement. Un tel dispositif est tout à fait semblable aux anomalies chaudes observées d'écoulement et peut avoir la même origine cote jour de la magnetopause trou d'air magnetosphere de la Terre le vent solaire reconnexion Particle-in-Cell code (PIC) bow shock
118	The study of interplanetary shocks, geomagnetic storms, and substorms with the WINDMI model Mays, Mona Leila 24 March 2011 (has links) WINDMI is a low dimensional plasma physics-based model of the coupled magnetosphere-ionosphere system. The nonlinear system of ordinary differential equations describes the energy balance between the basic nightside components of the system using the solar wind driving voltage as input. Of the eight dynamical variables determined by the model, the region 1 field aligned current and ring current energy is compared to the westward auroral electrojet AL index and equatorial geomagnetic disturbance storm time Dst index. The WINDMI model is used to analyze the magnetosphere-ionosphere system during major geomagnetic storms and substorms which are community campaign events. Numerical experiments using the WINDMI model are also used to assess the question of how much interplanetary shock events contribute to the geoeffectiveness of solar wind drivers. For two major geomagnetic storm intervals, it is found that the magnetic field compressional jump is important to producing the changes in the AL index. Further, the WINDMI model is implemented to compute model AL and Dst predictions every ten minutes using real-time solar wind data from the ACE satellite as input. Real-Time WINDMI has been capturing substorm and storm activity, as characterized by the AL and Dst indices, reliably since February 2006 and is validated by comparison with ground-based measurements of the indices. Model results are compared for three different candidate input solar wind driving voltage formulas. Modeling of the Dst index is further developed to include the additional physical processes of tail current increases and sudden commencement. A new model, based on WINDMI, is developed using the dayside magnetopause and magnetosphere current systems to model the magnetopause boundary motion and the dayside region 1 field aligned current which is comparable to the auroral upper AU index. / text WINDMI Coupled magnetosphere-ionosphere system Field aligned current Ring current energy Auroral electrojet AL index Geomagnetic storms Solar wind drivers
119	Un modèle à criticalité auto-régulée de la magnétosphère terrestre Vallières-Nollet, Michel-André January 2009 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal Magnétosphère Queue de la magnétosphère Sous-orage géomagnétique Criticalité auto-régulée Exposants critiques Complexité Magnetosphere Magnetotail Substorm Self-organized criticality Critical exponents Complexity
120	Numerical modelling of ultra low frequency waves in Earth's magnetosphere Elsden, Tom January 2016 (has links) Ultra Low Frequency (ULF) waves are a ubiquitous feature of Earth's outer atmosphere, known as the magnetosphere, having been observed on the ground for almost two centuries, and in space over the last 50 years. These waves represent small oscillations in Earth's magnetic field, most often as a response to the external influence of the solar wind. They are important for the transfer of energy throughout the magnetosphere and for coupling different regions together. In this thesis, various features of these oscillations are considered. A detailed background on the history and previous study of ULF waves relevant to our work is given in the introductory chapter. In the following chapters, we predominantly use numerical methods to model ULF waves, which are carefully developed and thoroughly tested. We consider the application of these methods to reports on ground and spaced based observations, which allows a more in depth study of the data. In one case, the simulation results provide evidence for an alternative explanation of the data to the original report, which displays the power of theoretical modelling. An analytical model is also constructed, which is tested on simulation data, to identify the incidence and reflection of a class of ULF wave in the flank magnetosphere. This technique is developed with the aim of future applications to satellite data. Further to this, we develop models both in Cartesian and dipole geometries to investigate some of the theoretical aspects of the coupling between various waves modes. New light is shed on the coupling of compressional (fast) and transverse (Alfvén) magnetohydrodynamic (MHD) wave modes in a 3D dipole geometry. Overall, this thesis aims to develop useful numerical models, which can be used to aid in the interpretation of ULF wave observations, as well as probing new aspects of the existing wave theory.

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