Dissertations / Theses on the topic 'Ganymedes'

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The present dissertation is located in the line of research entitled "Text and Discourse in Oral and Written Modalities", part of the Program of Postgraduate Studies in Portuguese Language, Pontifical Catholic University of São Paulo - PUC / SP. The central theme of this research is to analyze, from the perspective of the Discourse Analysis (AD) of the French line, the exclusion between two novels of Ganymédes José, namely: My Name is Hope!, 1974, and Hearts of Stone, The aim is to approach literature as a producer of discourse that is constituted in - and by - language; thus, it is necessary to observe the socio-historical conditions, in order to situate the discourses contemplated for analysis. The selected theme is justified by the observations made during the student environment, during a course in Basic Education, in contact with deaf students, at which time it was possible to verify the presence of exclusion. The research problem raised was to verify the way in which the writer positioned himself and constituted his discourses in the different contexts before the exclusions. Based on studies carried out by Maingueneau, the present investigation aims at the observation: of the role of interdiscourse in the consideration of the effects of sense and in the interweaving of different universes; of scenography, with the development of the enunciation constituted between the enunciator, co-enunciator, involving the topography and the chronography; and of ethos in the construction of the image of the enunciator accomplished by the co-enunciator and its process of incorporation. This study reveals the importance of theoretical and methodological procedures to favor the knowledge of discourse
A presente dissertação situa-se na linha de pesquisa intitulada “Texto e Discurso nas Modalidades Oral e Escrita”, integrante do Programa de Estudos Pós-Graduados em Língua Portuguesa, da Pontifícia Universidade Católica de São Paulo – PUC/SP. O tema central desta pesquisa é analisar, sob a perspectiva da Análise do Discurso (AD) de linha francesa, a exclusão entre dois romances de Ganymédes José, quais sejam: Meu Nome é Esperança!, do ano de 1974, e Corações de Pedra, de 1984. O intuito é abordar a literatura como produtora de discurso que se constitui na – e pela – linguagem; assim sendo, faz-se necessário observar as condições sócio-históricas, a fim de situar os discursos contemplados para análise. O tema selecionado se justifica a partir das observações realizadas no meio estudantil, durante percurso na Educação Básica, em contato com alunos surdos, ocasião em que foi possível constatar, ainda, a presença da exclusão. O problema de pesquisa levantado foi o de verificar o modo como o escritor se posicionou e constituiu seus discursos nos diferentes contextos frente às exclusões. Partindo de estudos realizados por Maingueneau, a presente investigação visa à observação: do papel do interdiscurso na consideração dos efeitos de sentido e no entrelaçamento de diferentes universos; da cenografia, com o desenvolvimento da enunciação constituída entre o enunciador, co-enunciador, envolvendo a topografia e a cronografia; e do ethos na construção da imagem do enunciador realizada pelo co-enunciador e seu processo de incorporação. Esse estudo revela a importância dos procedimentos teóricos e metodológicos em favorecer o conhecimento do discurso

Ganymede, one of Jupiters moons, differs from other moons in the Solar System as it has its own magnetic field. This rare property shapes the morphology on the existing far ultraviolet oxygen auroral ovals on the celestial body in the northern and southern hemisphere created by high energy electrons colliding into the atmosphere.With the help of the Hubble Space Telescope (HST) this phenomenon has been captured and analyzed multiple times during the past 20 years using the on-board Space Telescope Imaging Spectrograph (STIS). The ultimate goal of this project is recreating the far ultraviolet oxygen auroral emissions on Ganymede as a 3D computer model in MATLAB by using the data recovered from HST.The method used to reach this goal was to implement a model with main characteristics of the auroral ovals, project it onto a plane and then use a Cauchy distribution to filter the model. To compare the model with images from HST, a χ2-value was calculated for every pixel in each image. To further improvethe model the Nelder-Mead Simplex optimization method was applied.The project succeeded in such a way that the final model created views of the locations and the appearance of the bright spots that represent the auroral ovals around Ganymede with an accurate result in relation to the given data.

The electrodynamic interaction of Ganymede’s mini-magnetosphere with Jupiter’s corotating magnetospheric plasma has been shown to give rise to strong current systems closing through the moon and its ionosphere as well as through its magnetopause and magnetotail current sheet. This interaction is strongly evidenced by the presence of aurorae at Ganymede and of a bright Ganymede footprint on Jupiter’s ionosphere. This footprint is located equatorward of the main auroral emissions, at the magnetic longitude of the field line threading Ganymede. The brightness of Ganymede’s auroral footprint at Jupiter along with its latitudinal position have been shown to depend on the position of Ganymede relative to the center of the Jovian plasma sheet. Additionally, observations using the Hubble Space Telescope showed that Ganymede’s auroral footprint brightness is characterized by variations of three different timescales: 5 hours, 10-40 minutes, and ~100 seconds. The goal of the present study is to examine the relationship between the longest and the shortest timescale periodicities of Ganymede’s auroral footprint brightness and the local processes occurring at Ganymede. This is done by coupling a specifically developed brightness model to a three-dimensional multifluid model which tracks the energies and fluxes of the various sources of charged particles that precipitate into Ganymede’s ionosphere to generate the aurora. It is shown that the predicted auroral brightnesses and morphologies agree well with observations of Ganymede’s aurora from the Hubble Space Telescope. Our results also suggest the presence of short- and long-period variabilities in the auroral emissions at Ganymede due to magnetic reconnections on the magnetopause and in the magnetotail, and support the hypothesis of a correlation between the variability of Ganymede’s auroral footprint on Jupiter’s ionosphere and the variability in the brightness and morphology of the aurora at Ganymede. Finally, the modeled aurora at Ganymede reveals that the periodicities in the morphology and brightness of the auroral emissions are produced by two different dynamic reconnection mechanisms. The Jovian flow facing side aurora is generated by electrons sourced in the Jovian plasma and penetrating into Ganymede’s ionosphere through the cusps above the separatrix region. In this case, the reconnection processes responsible for the auroral emissions occur on Ganymede’s magnetopause between the Jovian magnetic field lines and the open magnetic field lines threading Ganymede’s Polar Regions. As for the magnetotail side aurora, it is generated by electrons originating from Ganymede’s magnetospheric flow. These electrons are accelerated along closed magnetic field lines created by magnetic reconnection in Ganymede’s magnetotail, and precipitate into Ganymede’s ionosphere at much lower latitudes, below the separatrix region.

Ganymedes är största månen i vårt Solsystem, och är ett föremål för intensiv vetenskaplig forskning under senaste decenier. Sedan 1998, STIS (Space Telescope Imaging Spectrograph) instrumentet ombord rymdteleskopet Hubble (HST) har observerat Ganymedes i UV ljus med våglängder mellan 1150 Å och 1730 Å i fem olika omgångar. Bilder av månen har tagits när Ganymedes var i olika positioner i sin bana. Detta gör det möjligt att jämföra båda hemisfärer av månen, och att undersöka eventuell tidsvariation. I denna rapport HST/STIS observationer av Ganymedes analyseras med målsättningen att undersöka månens exosfär bestående av atomär syre samt månens albedo i FUV våglänger. Väteexosfären, också kallad korona, förväntas sprida Lyman- ljuset vid 1216 Å, som kan observeras av STIS. Observationer i denna våglängd analyseras och en modell är framtagen för olika källor som bidrar vid denna våglängd. En uppskattning görs också av en eventuell absorption av Ganymedes emissioner i Jordens övre atmosfär, som kan uppgå till 85%. Jämförelse av modellen med bilder från HST/STIS tyder på att Ganymedes har en väteexosfär med ytdensiteten av (2-8) 103 cm􀀀3. Under Hubble kampanj 13328 har däremot betydligt lägre antal väteatomer detekterats, som kan bero på skillnader i magnetosfäriska omgivningen av månen jämfört med tidigare observationer. FUV albedo av månens yta har undersökts genom jämförelser av reflektansen vid olika våglängder, inklusive eventuella skillnader mellan olika hemisfärer. Vi finner att bakre (i förhållande till rörelsen i banan, som månen är låst i) hemisfären är ljusare än främre hemisfären för < 1600 Å. För längre våglängder, > 2000 Å, har motsatta resultat rapporterats tidigare, där främre hemisfären var ljusare. Detta tyder på att Ganymedes ytreflektans har en spektral inversion mellan 1600-2000 Å. Vi noterar även att ytreflektansen ökar med kortare våglängd för < 1400 Å, som kan bero på att ytans växelverkan med rymdpartiklar.
Ganymede, the largest moon in our Solar System, has been a target for intensive scientific research during the past decades. Since 1998, the Space Telescope Imaging Spectrograph (STIS) onboard of the Hubble Space Telescope (HST) has observed it in five different HST campaigns, operating in a wavelength range between 1150-1730 Å. The images were obtained when Ganymede was located at different orbital phase, providing information about both the trailing and leading hemispheres, and allowing for the search of potential hemispherical and time variability. Here, we analyze Ganymede’s HST/STIS observations in the search for a hydrogen exosphere and the study of the far-ultraviolet (FUV) albedo at different wavelengths. The hydrogen corona is expected to scatter sunlight at the Lyman- wavelength (1216 Å), which is within STIS’ spectral range. We analyze the observations at this particular wavelength, and derive models for the different sources of emission that are expected to contribute to the signal. We also estimate the potential extinction of Ganymede’s coronal emissions in the Earth’s upper atmosphere, which can be up to 85%. The comparison between the HST/STIS images and the model allows us to detect the hydrogen exosphere, which we estimate to be in a range of approximately (2-8) 103 cm􀀀3. The atomic hydrogen abundance in Ganymede’s atmosphere during HST campaign 13328 appears to be significantly lower, which could be related to differences in the plasma magnetospheric environment. We study Ganymede’s FUV albedo comparing the reflectance at different wavelengths, and potential difference between leading and trailing hemispheres. We find out that the trailing hemisphere is brighter than the leading side for < 1600 Å. This dichotomy is opposite to the previous results reported for > 2000 Å, where the leading hemisphere is actually brighter. Hence, there is a spectral inversion of Ganymede’s surface reflectivity at some wavelength in the range 1600-2000 Å. We also find out that the reflectivity of the surface increases for < 1400 Å, which might be related to space weathering processes on the surface.

Focusing on Ganymede and Enceladus, this work addresses a number of issues regarding icy satellite evolution, including the ultimate cause of Ganymede's tectonic and cryovolcanic resurfacing, the production of Ganymede's magnetic field, the formation of Ganymede's grooved terrain, and the tectonic and thermal evolution of Enceladus.Both Ganymede's resurfacing and the production of its magnetic field may be attributable to the Galilean satellites' passage through a Laplace-like resonance that excited Ganymede's orbital eccentricity. I examine how resonance passage effects Ganymede's thermal evolution using a coupled orbital-thermal model. Dissipation of tidal energy in Ganymede's ice shell permits high heat fluxes in its past, consistent with the formation of the grooved terrain; however, it also leads to the formation of a thin ice shell, which would have significant consequences for Ganymede's geologic history. In contrast, negligible tidal dissipation occurs in Ganymede's silicate mantle. Thus, passage through a Laplace-like resonance cannot reinvigorate Ganymede's metallic core or enable present-day magnetic field generation.Ganymede's thermal evolution has driven tectonic deformation on its surface, producing numerous swaths of ridges and troughs termed ``grooved terrain.'' Grooved terrain likely formed via unstable extension of Ganymede's lithosphere, but questions regarding instability growth at large strains remain unanswered. To address these questions, I use the finite-element model TEKTON to simulation the extension of an icy lithosphere to examine instability growth at finite strains. My results indicate that large-amplitude deformation requires lower thermal gradients than have been suggested by analytical models; however, the maximum deformation amplitudes produced by our numerical models are lower than typical observed groove amplitudes.Finally, I apply our finite-element modeling to the formation of ridges and troughs on Enceladus. Comparison between our models and photoclinometry profiles of Enceladus' topography indicate that the heat flux was high at the time of ridge and trough formation. Thus, the tectonic resurfacing and high heat fluxes currently observed at Enceladus' south pole may be only the latest episode in a long history of localized resurfacing and global reorientation.

In 1979, the IRIS infrared spectrometers on the two Voyager spacecraft obtained over 1000 disk-resolved thermal emission spectra of Europa, Ganymede, and Callisto, Jupiter's three large icy satellites. This dissertation describes the first detailed analysis of this data set. Ganymede and Callisto subsolar temperatures are 10°K and 5°K respectively below equilibrium values. Equatorial nighttime temperatures are between 100°K and 75°K, Callisto and Europa being colder than Ganymede. The diurnal temperature profiles can be matched by 2-layer surfaces that are also consistent with the eclipse cooling observed from earth, though previous eclipse models underestimated thermal inertias by about 50%. Substrate thermal inertias in the 2-layer models are a factor of several lower than for solid ice. These are 'cold spots' on Ganymede and Callisto that are not high-albedo regions, which may indicate large thermal inertia anomalies. All spectra show a slope of increasing brightness temperature with decreasing wavelength, indicating local temperature contrasts of 10-50°K. Callisto spectra steepen dramatically towards the terminator, a trend largely matched with a laterally-homogeneous model surface having lunar-like roughness, though some lateral variation in albedo and/or thermal inertia may also be required. Subsolar Ganymede spectra are steeper than those on Callisto, but there is no steepening towards the terminator, indicating a much smoother surface than Callisto's. The spectrum slopes on Ganymede may indicate large lateral variations in albedo and thermal inertia. A surface with similar areal coverage of dark, very low thermal inertia material, and bright material with thermal inertia a factor of 2-3 below solid ice, fits the diurnal and eclipse curves, and (less accurately) the IRIS spectrum slopes. Europa spectra have very small slopes, indicating a smooth and homogeneous surface. Modelling of surface water ice migration gives a possible explanation for the inferred lateral inhomogeneities on Ganymede. Dirty ice surfaces at Jupiter are subject to segregation into high-albedo ice-rich cold spots and ice-free regions covered in lag deposits, on decade timescales. Ion sputtering and micrometeorite bombardment are generally insufficient to prevent the segregation. The reflectance spectra of Ganymede and Callisto may be consistent with this type of segregated surface.

On se propose dans un premier temps d'étudier des jeux de données topographiques sur la lune glacée de Jupiter Ganymède et d'estimer l'impact de la topographie sur les performances du futur radar sondeur. Les principaux résultats sont présentés dans [1]. Une seconde partie est dédiée à l'expression mathématique du problème direct du sondage radar planétaire (physique et instrumentation). On rappelle ainsi comment dériver à partir des formulations de Stratton-Chu les formulations volumiques classiques et surfaciques (i.e. Huygens-Fresnel). On s'attache ensuite à détailler un algorithme performant basé sur la formulation surfacique pour simuler des échos radar à partir d'une surface planétaire maillée. Cette approche est largement inspirée par le travail de J.-F. Nouvel [2]. Une troisième partie s'intéresse à l'inversion des paramètres géophysiques de surface à partir des mesures radar. On écrit ainsi le problème dans un cadre probabiliste (c.f. [3]) et on présente trois grandes familles d'algorithmes : (i) une approche avec une linéarisation du problème, (ii) une approche itérative basée sur une méthode de gradient et (iii) une approche statistique pour estimer les densités de probabilités a posteriori. Ces algorithmes sont appliqués à des jeux de données synthétiques pour illustrer leurs performances. [1] Y. Berquin, W. Kofman, A. Herique, G. Alberti, and P. Beck. A study on ganymede's surface topography: Perspectives for radar sounding. Planetary and Space Science, (0), 2012. [2] J.-F. Nouvel, A. Herique, W. Kofman, and A. Safaeinili. Radar signal simulation: Surface modeling with the Facet Method. Radio Science, 39:RS1013, February 2004. [3] A. Tarantola. Inverse problem theory and methods for model parameter estimation. SIAM, 2005
The manuscript details the work performed in the course of my PhD on planetary sounding radar. The main goal of the study is to help designing and assessing the sounding radar performances. This instrument will be embarked on the ac{ESA}'s large class mission ac{JUICE} to probe Jupiter's environment and Jupiter's icy moons Callisto, Ganymede and Europa. As an introduction to the problem, a study on Ganymede's surface ac{DEM} and its implications with regard to the radar performances was performed. The results of this work put forward issues due to a hostile environment with important surface clutter which eventually lead to a decrease in the radar signal bandwidth to 8--10 MHz. A first section is then dedicated to the formulation of the direct problem of sounding radar with a focus on surface formulations. This section eventually leads to a novel algorithm for radar surface echo computation from meshed surfaces which proves to be both efficient and accurate. A second section studies the possibility to use surface formulation to recover geophysical surface parameters from sounding radar data. For that purpose, three main approaches are discussed namely (i) a linear approach, (ii) a gradient-based approach and (iii) a statistical approach. These techniques rely on a probabilistic view of the inverse problem at hand and yield good result with different setups. Although we mainly focus on surface reflectivity, we also discuss surface topography inversion. Finally, a last section discusses the work presented in the manuscript and provides perspectives for future work

Ganymède, une lune de Jupiter, est le plus grand et le plus massif des satellites de notre système solaire. Cet objet a été observé depuis la Terre, notamment grâce au télescope Hubble (HST), et in situ par la sonde Galileo. Grâce à ces observations, une atmosphère très ténue, ou exosphère,principalement composée d'hydrogène, d'oxygène et d'oxygène moléculaire, a été détectée au voisinage de Ganymède. Ganymède est l'unique lune du système solaire possédant son propre champ magnétique intrinsèque, qui, en interagissant avec le plasma magnétosphérique jovien, génère unemini-magnétosphère. Cette magnétosphère est imbriquée dans celle de Jupiter. C'est le seul cas connu d'interaction entre deux magnétosphères. Galileo est l'une des seules sondes spatiales ayant investigué l'environnement complexe de Ganymède. La prochaine mission spatiale qui étudiera ce satellite estune mission européenne de l'ESA : JUICE (JUpiter ICy moon Exploration). Dans le cadre de cette mission, et dans un but de mieux connaître ce satellite, mon travail de thèse a consisté à modéliser l'environnement global neutre et ionisé de Ganymède.La première partie de mon travail de thèse a été consacrée à l'étude de l'exosphère de Ganymède à l'aide d'un modèle 3D Monte-Carlo. J'ai parallélisé ce modèle afin d'améliorer ses performances et d'enrichir la physique décrite par le modèle. Les résultats sont comparés à ceux d'autres modèles, ainsi que les observations effectuées par le HST et Galileo. L'environnement ionisé, en particulier la magnétosphère de Ganymède, a été ensuite étudié à l'aide d'un modèle hybride parallèle 3D, notamment en se plaçant dans les conditions d'observations de Ganymède par Galileo. Les résultats sont globalement cohérents avec les observations, et concordent avec ceux d'autres modèles, maismontrent néanmoins une nécessité d'améliorer significativement la résolution spatiale du modèle. De ce fait, une partie significative de mon travail de thèse a été dédiée au développement et à l'implémentation d'une approche multi-grilles au sein du modèle hybride, pour améliorer la résolution spatiale d'un facteur 2 dans le voisinage proche du satellite. Enfin, les résultats obtenus avec ce modèle optimisé sont confrontés aux observations de Galileo
Jupiter’s moon Ganymede is the biggest and most massive satellite of our solar system. Thisobject has been observed from the Earth, with the Hubble Space Telescope (HST), and through in situ measurements by Galileo spacecraft. Thanks to these observations, a very tenuous atmosphere, or exosphere, has been detected at Ganymede. It is mainly composed of atomic hydrogen, atomic oxygen, and molecular oxygen. Ganymede is the only moon of the solar system to have its own intrinsic magnetic field, which generates a minimagnetosphere interacting with the magnetospheric jovian plasma. This magnetosphere is embedded in the jovian magnetosphere. It is the only known case of interaction between two magnetospheres. Galileo is the only mission that has investigated the complex ionized environment of Ganymede. The next space mission dedicated to investigate the Jovian magnetosphere and its galilean satellite is an European mission from ESA : JUICE (Jupiter ICy moons Explorer). In the frame of this mission, and to prepare future observations at Ganymede, my thesis work has consisted in modeling the global neutral and ionized environment of Ganymede. The first part of my thesis work has been dedicated to the study of Ganymede’s exosphere with a 3D Monte-Carlo model. I have parallelized this model to improve its performance and to enrich the physics described by the model. Results have been compared to those of other models, and to HST and Galileo observations. The ionized environment, in particular the magnetosphere of Ganymede, has then been studied with a 3D parallel hybrid model,considering the observation conditions of Galileo. Results are globally consistent with the observations and with other models, but show the necessity to significantly improve the spatial resolution. Therefore, a significant part of my work has been dedicated to the development of a multi-grid approach in the hybrid model, to divide by 2 the spatial resolution at the vicinity of Ganymede. Finally, results obtained with the optimized model are compared to Galileo observations

Over the last fifty years, our knowledge of the Solar System has increased exponentially. Many planetary surfaces were seen for the first time through spacecraft observations. Yet the interiors of most planetary bodies remain poorly studied. This dissertation focuses on two main topics: the formation of central pit craters and what this reveals about the subsurface volatile content of the target material, and the mantle dynamics of Io and how they relate to the extensive volcanism on its surface. Central pit craters are seen on icy satellites, Mars, the Moon, and Mercury. They have terraced rims, flat floors, and a pit at or near their center. Several formation mechanisms have been suggested. This dissertation assesses the feasibility of central pit crater formation via drainage of impact melt through impact-generated fractures. For impacts on Ganymede, the expected volume of melt and volume of fracture space generated during the impact and the volume of melt able to drain before fractures freeze shut all exceed the observed central pit volumes on Ganymede. This suggests that drainage of impact melt could contribute to central pit crater formation on Ganymede. Molten rock draining through solid rock fractures will freeze shut more rapidly, so this work suggests that impact melt drainage is unlikely to be a significant factor in the formation of central pit craters on rocky bodies unless a significant amount of volatiles are present in the target. Io is the most volcanically active body in the Solar System. While volcanoes are most often associated with plate tectonics on Earth, Io shows no signs of plate tectonics. Previous work has suggested that Io could lose a significant fraction of its internal heat through volcanic eruptions. In this dissertation, I investigate the relationship between mantle convection and magma generation, migration by porous flow, and eruptions on Io. I couple convective scaling laws to a model solving the two-phase flow equations applied to a rising column of mantle. I show that Io has a partially molten upper mantle and loses the majority of its internal heat through volcanic eruption. Next, I present two-dimensional numerical simulations that self-consistently solve the two-phase flow equations including mantle convection and magma generation, migration by porous flow, and eruption. These simulations produce a high heat flux due to volcanic eruption, a thick lithosphere, a partially molten upper mantle, and a high eruption rate—all consistent with observations of Io. This model also reveals the eruption rate oscillates around the statistical steady state average eruption rate suggesting that the eruption rate and total heat flux measurements from the past 35 years may not be representative of Io's long term behavior.

La connaissance du flux UltraViolet (UV) solaire et de sa variabilité dans le temps est un problème clé aussi bien dans le domaine de l’aéronomie qu’en physique solaire. Alors que l’extrême UV, entre 10 et 121 nm, est important pour la caractérisation de l’ionosphère, l’UV entre 121 et 300 nm l’est tout autant pour les modélisations climatiques. La mesure continue de l’irradiance dans l’UV est cependant une tâche ardue. En effet, les instruments spatiaux étant dans un environnement hostile se dégradent rapidement. De nombreux modèles basés sur des indices solaires sont alors utilisées lorsque peu de données sont disponibles. Pourtant, l’utilisation de ces indices ne permet pas d’atteindre aujourd’hui une précision suffisante pour les différentes applications en météorologie de l’espace. Comme alternative, ce travail de thèse met en avant l’utilisation de bandes passantes pour reconstruire l’irradiance solaire dans l’UV. En utilisant des méthodes d’analyse statistique multivariée, ce travail met tout d’abord en évidence la forte cohérence de la variabilité spectrale de l’irradiance dans l’UV, ainsi que ses principales caractéristiques. Une première étape consiste à utiliser des bandes passantes existantes afin de tester la faisabilité de notre approche : le flux UV peut ainsi être reconstruit avec une erreur relative d’environ 20%, une bien meilleure performance qu’avec l’utilisation d’indices solaires. Afin de limiter les problèmes de dégradation liés à l’utilisation des filtres, nous proposons un instrument d’un genre nouveau basé uniquement sur des détecteurs à larges bande interdite permettant de sélectionner une bande spectrale (notamment pour l’UV à partir de 120 nm). Un tel radiomètre permettrait de reconstruire les raies spectrales importantes pour la spécification de la thermosphère terrestre avec une bonne précision. Enfin, une modélisation de l’impact du flux UV solaire sur l’atmosphère de Ganymède est exposée. Les émissions atmosphériques pour quelques espèces sont alors calculées, afin de proposer quelques recommandations pour les futures missions pour Jupiter
The knowledge of the solar spectral irradiance in the UV and its variation in time is a key problem in aeronomy but also in climatology and in solar physics. While the Extreme UV (10-121 nm) range is important for thermosphere/ionosphere specification, the Far UV and Middle UV ranges are essential for climate modelling. However, the continuous monitoring of the UV irradiance is a difficult task. Space instruments are indeed suffering from ageing but also signal contamination of many kinds. Because of the lack of long-term measurements of the whole UV range, most thermosphere/ionosphere and climate models rely today on proxies for the solar irradiance, which may however not reflect very well the variability. As an alternative, we proposed in this work to use a few radiometers with properly chosen passbands in order to reconstruct the solar UV irradiance. Using a multivariate statistical approach, we first characterize the high redundancy as well as the different features of the solar UV irradiance. With four passbands from already existing instrument, we test our concept : the solar UV flux is reconstructed with a relative error of about 20%. This work proposes then to define a new kind of instrument, which may use wide bandgap materials as detectors selecting moreover the spectral range without using filters. Filters are indeed very sensitive to the degradation. This new instrument could reconstruct very well some spectral lines important to the Earth thermosphere specification. This thesis finally proposes to model the impact of the solar UV flux on the atmosphere of Ganymede. We predict some atmospheric emissions in the framework of future space mission to Jupiter

Ce document contient un rapport scientifique résultant de plus de quatre années de recherche théorique et expérimentale sur un type particulier de systèmes physico-chimiques appelés hydrates de clathrates de gaz. Ces systèmes sont des composés d'inclusion constitués d'un cadre aqueux tridimensionnel contenant des molécules de gaz avec de faibles moments dipolaires dans leurs cavités. Les hydrates de clathrate de gaz sont très importants dans une grande variété de domaines scientifiques liés aux sciences de la vie ou à la planétologie, et ils sont également considérés comme une ressource naturelle principale pour l'industrie de l'énergie. Habituellement, les hydrates de clathrate de gaz nécessitent une pression élevée et une température basse pour être thermodynamiquement stables. En fonction de ces conditions, différentes phases ont été détectées, les plus courantes étant les structures cubiques sI et sII, la sH hexagonale et la structure de glace remplacée orthorhombique (FIS). Notre étude a considérablement progressé dans la connaissance du comportement du méthane et des hydrates de clathrate de dioxyde de carbone dans différentes conditions de pression et de température. En particulier, nous avons contribué à : (i) la détermination et la compréhension des régions thermodynamiques de stabilité, (ii) la caractérisation d'une structure haute pression controversée et (iii) la mise en place d'un nouvel équipement expérimental pour les mesures Raman dans une gamme de pression jusqu'à 1 GPa [...]
This document contains a scientific report resulting from more than four years of theoretical and experimental research on a particular kind of physicochemical systems called gas clathrate hydrates. These systems are inclusion compounds constituted by a three dimensional water framework hosting gas molecules with low dipolar moments in its cavities. Gas clathrate hydrates are very important in a great variety of scientific fields related to life sciences or planetology, and they are also considered as a main natural resource for the energy industry. Usually, gas clathrate hydrates need high pressure and low temperature to be thermodynamically stable. Depending on these conditions, differentphases have been detected being the most common ones the cubic structuressI and sII, the hexagonal sH, and the orthorhombic Filled Ice Structure(FIS). Our study has substantially advanced in the knowledge of the behaviorof methane and carbon dioxide clathrate hydrates under different pressure andtemperature conditions. In particular, we have contributed to: (i) the determination and understanding of stability thermodynamic regions, (ii) the characterizationof a controversial high-pressure structure, and (iii) setting up a new experimental equipment for Raman measurements in a pressure range up to 1 GPa [...]
Este documento contiene el informe científico resultante después de más de cuatro años de investigación teórica y experimental sobre un tipo particular de sistemas físico-químicos llamados clatratos hidratos de gas. Estos sistemas son compuestos de inclusión constituidos por un armazón tridimensional de agua que aloja en sus cavidades moléculas de gas con momentos dipolares bajos.Los clatratos hidratos de gas son muy importantes en una gran variedad de campos científicos relacionados con las ciencias de la vida o la planetología, y también se consideran como uno de los principales recursos naturales para la industria energética. Por lo general, los clatratos hidratos de gas necesitan alta presión y baja temperatura para ser termodinámicamente estables.Dependiendo de estas condiciones, se han detectado diferentes fases siendo las más comunes las estructuras cúbicas sI y sII, hexagonal sH y la estructura ortorrómbica de hielo relleno (FIS). Nuestro estudio ha avanzado sustancialmente en el conocimiento del comportamiento de los clatratos hidratos de metano y dióxido de carbono en diferentes condiciones de presión y temperatura, proporcionando (i) regiones termodinámicas de estabilidad, (ii) la caracterización de una estructura de alta presión controvertida y (iii) un nuevo equipo experimental para mediciones Raman en un rango de presión de hasta 1 GPa [...]

This thesis studies hydrated oxygen and hydroxyl radicals as a basis for understanding the species formed in the icy surfaces of outer solar system bodies. Infrared spectroscopy is used to identify the species water-oxygen (H2O·O2) and water-hydroxyl (H2O·HO) complexes in inert gas matrices and presents a new mechanism for O2 formation in irradiated ices. The H2O·O2 Complex -- The H2O·O2 complex was identified in solid argon matrices at 11 K by measuring the infrared spectra of H2O⁄O2⁄Ar matrices. Absorption bands at 3731.6, 3638.3, 1590.2⁄1593.6 and 1551.9⁄1548.8 cm-1 were respectively assigned to asymmetric OH water stretching, symmetric OH water stretching, H2O bending, and the O2 stretching vibrations. This experimental data was in good agreement with the results of quantum mechanical calculations that predict the vibrational frequencies and intensities for H2O·O2. These calculations gave a binding energy of 0.72 kcal mol-1 for the complex. The H2O·HO Complex -- The H2O·HO complex was identified in solid argon matrices at 11 K by measuring the infrared spectra of OH⁄H2O⁄Ar matrices. The OH was formed in a Tesla coil discharge of an H2O⁄Ar gas stream. This gas stream also provided the source of H2O and Ar needed for the experiments. Three absorption bands were assigned to the OH stretch of the hydroxyl group in the complex. These three bands were caused by the occupancy of three different lattice sites. This experimental data was in good agreement with quantum mechanical calculations that predict the vibrational frequencies and intensities for H2O·HO. These calculations gave a binding energy of 5.69 kcal mol-1 for the complex. O2 Formation in Irradiated Ice -- A new mechanism for O2 formation in irradiated ice is presented. This mechanism draws on experimental evidence in the literature to explain the observations of solid O2 on or near the surface of the icy Galilean satellites, Europa and Ganymede. It is proposed that on these bodies, hydrogen peroxide, formed from the radiolysis and photolysis of the ice, is present in highly localized aggregates that hinder O2 diffusion out of the icy surface into the tenuous atmosphere. Further radiolysis and photolysis of these hydrogen peroxide aggregates can then lead to O2 formation via the formation of a short lived water-oxygen atom complex, H2O·O. The O atoms of a pair of these complexes then react rapidly to form O2

Les satellites glacés de Jupiter sont d'un grand intérêt scientifique dans la recherche d'habitabilité au sein de notre système solaire. Elles abritent probablement toutes trois des océans d'eau liquide sous leur croûte glacée. Leurs surfaces présentent différents stades d’évolution – celle de Callisto est très ancienne et entièrement recouverte de cratères, celle de Ganymede est un mélange de terrains sombres et cratérisés et de plaines claires et plus jeunes et la surface d’Europa est la plus jeune et présente des signes d’activité récente. Cette thèse porte sur la photométrie, c’est à dire l’étude de l’énergie lumineuse réfléchie par une surface, en fonction des géométries d’éclairement et d’observation. Les études photométriques permettent de déterminer l’état physique et la microtexture des surfaces (porosité, structure interne, forme des grains, rugosité, transparence…). Une bonne connaissance photométrique est également d'une importance cruciale dans la correction des jeux de données pour toute étude cartographique ou spectroscopique ainsi que pour les futures missions de cette décennie : Europa Clipper de la NASA et JUpiter ICy Moons Explorer de l’ESA.Deux types d’information sont nécessaires pour réaliser une étude photométrique : des données de réflectance et des données géométriques (conditions d’illumination et d'observation). Pour obtenir les premières, nous avons utilisé et calibré des images de missions spatiales passées - Voyager, New Horizons et Galileo. Pour obtenir les secondes, nous avons développé des outils permettant de corriger les métadonnées de ces images (ex : la position et l'orientation des sondes) afin d’obtenir des informations géométriques précises. Nous avons, d’autre part, développé un outil d’inversion pour estimer les paramètres photométriques de Hapke sur des régions d’Europa, Ganymede et Callisto sur l’ensemble du jeu de données en un seul calcul. Enfin, nous discutons des liens possibles entre les paramètres photométriques estimés, la microtexture de la surface et les processus endogènes/exogènes mis en jeu
Jupiter's icy moons are of great interest in the search for habitability in our Solar System. They probably all harbor liquid water ocean underneath their icy crust. Their surfaces present different stages of evolution – Callisto is heavily cratered and the oldest, Ganymede shows a combination of dark cratered terrain and younger bright plains and Europa’s surface is the youngest with signs of recent and maybe current activity. This work focuses on photometry, i.e. the study of the light scattered by a surface in relation to the illumination and observation geometry. Photometric studies give us insight on the physical state and microtexture of the surface (compaction, internal structure, shape, roughness, transparency…). A good photometric knowledge is also of crucial importance in the correction of datasets for any mapping or spectroscopic study as well as for the future missions of this decade – NASA’s Europa Clipper and ESA’s JUpiter ICy moons Explorer.Two pieces of information are necessary to conduct a photometric study – reflectance data and geometric information (illumination, viewing conditions). For the former, we have used and calibrated images from past space missions – Voyager, New Horizons and Galileo. For the latter, we have developed tools to correct these images metadata (e.g. spacecraft position and orientation) to derive precise geometric information. Moreover, we have developed a Bayesian inversion tool to estimate Hapke’s photometric parameters on regions of Europa, Ganymede and Callisto. We estimate all parameters on our entire dataset at once. Finally, we discuss the possible links between the photometric parameters, the surface microtexture and endogenic/exogenic processes

The question of homoerotic sensibility is, in the purpose of this thesis, a matter of visual language connected to the portrayal of male bodies. By identifying this sensibility throughout the western art canon the essay seeks to understand its origins, development and function in relation to expressions of power. With the introduction of theorists such as Alois Riegl, Laura Mulvey, Abigail Solomon-Godeau and Raewyn Connell, the aim is to deconstruct homosexual masculinity. Adapting formal analysis and parts of visual semiotics, the focus lies on the visual expression of power through the homoerotic gaze, and asks what consequences it has in forming homosexual identity. Greek antiquity is home not only to the ideals that foster western art history, but is also where we find early examples of same-sex affection being portrayed in the arts. Hence classical antiquity is so important for the homoerotic: whenever the classical language of style is popular throughout history, we are sure to find homoerotic sensibility. For reasons mentioned, the main periods analyzed are the Italian Renaissance, the French Neoclassicism and then, naturally the late 20th century onwards as this is the period of gay liberation and modern homosexual identity.  By identifying classical acceptance of homosexual relations only in the form of a clear social hierarchy, we soon discover how homosexuality has appropriated the idea of binary difference within its masculinity throughout history. Accepting relationships only between erastes and eromenos, or man and ephebe, homosexuality is forced to exist only on the terms of difference of power. With classical ideals, these tendencies are recurring in the visual representation of male homosexuality, and becomes a big part of the liberation and forming of a modern identity in the late twentieth century. As a result of objectification of the male body, in combination with idealized and sexualized power, modern gay culture has in many ways embraced a destructive culture shaped by misogynist ideas of hegemonic culture, where sexual violence exists, but is not spoken of.

The work is divided into three independent papers:

PAPER I:

Thermal evolution models are presented for Ganymede, assuming a mostly differentiated initial state of a water ocean overlying a rock layer. The only heat sources are assumed to be primordial heat (provided by accretion) and the long-lived radiogenic heat sources in the rock component. As Ganymede cools, the ocean thins, and two ice layers develop, one above composed of ice I, and the other below composed of high-pressure polymorphs of ice. Subsolidus convection proceeds separately in each ice layer, its transport of heat calculated using a simple parameterized convection scheme and the most recent data on ice rheology. The model requires that the average entropy of the deep ice layer exceed that of the ice I layer. If the residual ocean separating these layers becomes thin enough, then a Rayleigh-Taylor-like ("diapiric") instability may ensue, driven by the greater entropy of the deeper ice and merging the two ice mantles into a single convective layer. This instability is not predicted by linear analysis but occurs for plausible finite amplitude perturbations associated with large Rayleigh number convection. The resulting warm ice diapirs may lead to a dramatic "heat pulse" at the surface and to fracturing of the lithosphere, and may be directly or indirectly responsible for resurfacing and grooved terrain formation on Ganymede. The timing of this event depends rather sensitively on poorly known rheological parameters but could be consistent with chronologies deduced from estimated cratering rates. Irrespective of the occurrence or importance of the heat pulse, we find that lithospheric fracturing requires rapid stress loading (on a timescale ≾ 10⁴) years). Such a timescale can be realized by warm ice diapirism, but not directly by gradual global expansion. In the absence of any quantitative and self-consistent model for the resurfacing of Ganymede by liquid water, we favor resurfacing by warm ice flows,which we demonstrate to be physically possible, a plausible consequence of our models, compatible with existing observations, and a hypothesis testable by Galileo. We discuss core formation as an alternative driver for resurfacing, and conclude that it is less attractive. We also consider anew the puzzle of why Callisto differs so greatly from Ganymede, offering several possible explanations. The models presented do not provide a compelling explanation for all aspects of Ganymedean geological evolution, since we have identified several potential problems, most notably the apparently extended period of grooved terrain formation (several hundred million years), which is difficult to reconcile with the heat pulse phenomenon.

PAPER II:

The observed zonal flows of the giant planets will, if they penetrate below the visible atmosphere, interact significantly with the planetary magnetic field outside the metalized core. The appropriate measure of this interaction is the Chandrasekhar number Q = (H²)/(4πρνα²λ) (where H = radial component of the magnetic field, ν = eddy viscosity, λ = magnetic diffusivity, α^-1 = lengthscale on which λ varies); at depths where Q ≳ 1 the velocity will be forced to oscillate on a small lengthscale or decay to zero. We estimate the conductivity due to semiconduction in H² (Jupiter, Saturn) and ionization in H²O (Uranus, Neptune) as a function of depth; the value λ ≃ 10¹⁰ cm²s^-1 needed for Q = 1 is readily obtained well outside the metallic core (where λ ≃ 10² cm²s^-1).

These assertions are quantified by a simple model of the equatorial zonal jet in which the flow is assumed uniform on cylinders concentric with the spin axis, and the viscous and magnetic torques on each cylinder are balanced. We solve this "Taylor constraint" simultaneously with the dynamo equation to obtain the velocity and magnetic field in the equatorial plane. With this model we reproduce the widely differing jet widths of Jupiter and Saturn (though not the flow at very high or low latitudes) using ν = 2500 cm²s^-1, consistent with the requirement that viscous dissipation not exceed the specific luminosity. A model Uranian jet consistent with the limited Voyager data can also be constructed, with appropriately smaller ν, but only if one assumes a two-layer interior. We tentatively predict a wide Neptunian jet.

For Saturn (but not Jupiter or Uranus) the model has a large magnetic Reynolds number where Q = 1 and hence exhibits substantial axisymmetrization of the field in the equatorial plane. This effect may or may not persist at higher latitudes. The one-dimensional model presented is only a first step. Variation of the velocity and magnetic field parallel to the spin axis must be modeled in order to answer several important questions, including: 1) What is the behavior of flows at high latitudes, whose Taylor cylinders are interrupted by the region with Q ≳ 1? 2) To what extent is differential rotation in the envelope responsible for the spin-axisymmetry of Saturn's magnetic field?

PAPER III:

It is shown that the problem of two-dimensional photoclinometry (PC) -- the reconstruction of a surface z(x,y) from a brightness image B(x,y) -- may be formulated in a natural way in terms of finite elements. The resulting system of equations is underdetermined as a consequence of the lack of boundary conditions for z, but a unique solution may be chosen by minimizing a function S expressing the "roughness" of the surface. An efficient PC algorithm based on this formulation is presented, requiring ~ 10.66 (four-byte) memory locations and ~10⁴ floating multiplications/additions per pixel, and incorporating: 1) Minimization of the roughness by the penalty method, which yields the smallest set of equations. 2) Iterative solution of the nonlinear equations by Newton's method. 3) Solution of the linearized equations by an inner iterative cycle of successive over-relaxation, which takes advantage of the extreme sparseness of the system. 4) Multigridding, in which the solutions to the smaller problems obtained by reducing the resolution are used recursively to greatly speed convergence at the higher resolutions, and 5) A rapid noniterative initial estimate of z obtained by exploiting the special symmetry of the equations obtained in the first linearization.

The algorithm is extensively demonstrated on 200 by 200 pixel synthetic "images" generated from digital topographic data for northern Utah over a range of phase angles. Rms error in the solution is ~ 22 m, out of ~ 660 m total relief. The error is dominated by "stripes" with the same azimuth as the light source, resulting from use of the roughness criterion in lieu of boundary conditions; the rms error along profiles parallel to the stripes is only ~ 2-8 m, depending on the phase angle. Satisfactory solutions are obtained even in the presence of quantization error, noise, and moderate blur in the image.

Applications of the PC algorithm to both remote sensing and photomicrography are sketched; a photoclinometric map of a low-relief Precambrian era fossil is presented as an example of the latter. Prospects for dealing with photometrically inhomogeneous surfaces, and an extension of the method to the analysis of side-looking radar data ("radarclinometry") are also discussed.