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Multi-messenger emission from gamma-ray burstsSamuelsson, Filip January 2020 (has links)
Multi-messenger astronomy is a very hot topic in the astrophysical community. A messenger is something that carries information. Different astrophysical messenger types are photons, cosmic rays, neutrinos, and gravitational waves. They all carry unique and complementary information to one another. The idea with multi-messenger astronomy is that the more different types of messengers one can obtain from the same event, the more complete the physical picture becomes. In this thesis I study the multi-messenger emission from gamma-ray bursts (GRBs), the most luminous events known in the Universe. Specifically, I study the connection of GRBs to extremely energetic particles called ultra-high-energy cosmic rays (UHECRs). UHECRs have unknown origin despite extensive research. GRBs have long been one of the best candidates for the acceleration of these particles but a firm connection is yet to be made. In Paper I and Paper II, we study the possible GRB-UHECR connection by looking at the electromagnetic radiation from electrons that would also be accelerated together with the UHECR. My conclusion is that the signal from these electrons does not match current GRB observation, disfavoring that a majority of UHECRs comes from GRBs. / ”Multi-messenger astronomy” (mångbudbärarastronomi, fri översättning) är ett väldigt aktuellt område inom astrofysiken just nu. En meddelare är någonting som bär på information. Olika meddelartyper inom astrofysiken är fotoner, kosmisk strålning, neutriner och gravitations vågor. Dessa har alla unik och olika typ av information som kompletterar varandra. Idén bakom multi-meddelare-astronomi är att ju fler olika meddelartyper vi kan upptäcka från samma event, desto mer komplett blir vår fysikaliska tolkning. I denna avhandling studerar jag multi-meddelare emission från gammablixtar (GRBs), de mest ljusstarka företeelser vi känner till i Universum. Mer specifikt, så studerar jag kopplingen mellan GRBs och ultraenergetisk kosmisk strålning (UHECRs). Ursprunget till UHECRs är fortfarande okänt trots långt pågående forskning. GRBs har länge varit en av de mest lovande accelerationskandidaterna men än så länge finns inga fasta bevis. I Paper I och Paper II studerar vi den möjliga GRB-UHECR kopplingen genom att studera den elektromagnetiska strålningen från elektronerna som även de skulle bli accelererade tillsammans med UHECRs. Min slutsats är att strålningen från elektronerna inte matchar observationer från GRBs, vilket talar emot att en majoritet av UHECRs kommer från GRBs.
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Fitting a photospheric prompt emission model to GRB data: The Kompaneets RMS approximation (KRA) / Anpassning av en fotosfärisk gamma-blixt modell till data: The Kompaneets RMS Approximation (KRA)Wistemar, Oscar January 2023 (has links)
Gamma-ray bursts (GRBs) are some of the most energetic events in the universe. Shocks occurring below the photosphere are likely radiation mediated shocks (RMSs) and are suspected to shape the spectra. Due to computational costs of simulating RMSs, models had not been fitted to data and a faster model was needed. The Kompaneets RMS Approximation (KRA) is an analog model of RMSs, creating spectra which are identical to full RMS simulation spectra and it is significantly faster. For a sample of short GRBs I found that spectra are very hard and close to a non-dissipative photosphere (NDP). Therefore any trace of energy dissipation is lost to thermalization and many KRA solutions are possible with statistics similar to the Band model. A sample of long GRBs have typical spectra, i.e. spectra much broader than a blackbody (BB) and the KRA can model these spectra very well. Statistically, KRA is as good as the Band model and significantly better for GRB211211. I also found two spectral shapes describing observed data equally well. First, a broadened BB for a steady-state outflow, and secondly, optically shallow shocks for a non steady-state outflow. To distinguish between these solutions, upcoming detectors with lower-energy data are important. In conclusion, the KRA can reproduce photospheric spectra altered by a RMS, and these spectra can explain observed GRB spectra. If the spectrum is not thermalized, information about the properties of the shock can be deduced from observed GRB spectra. / Gamma-blixtar är några av de mest energirika händelserna i universum. Chocker som uppkommer under fotosfären är troligtvis strålnings medlade chocker (RMSer) och misstänks forma spektra. Höga beräkningsmässiga kostnader för simuleringar av RMSer har lett till att modeller inte har anpassats till data. The Kompaneets RMS Approximation (KRA) är en analog modell av RMSer som skapar identiska spektra och är mycket snabbare. För ett urval av korta gamma-blixtar hittar jag väldigt hårda spektra, nära en icke-dissiperad fotosfär (NDP). Alla spår av dissipering har därför försvunnit p.g.a. termaliseringen och många olika KRA lösningar kan anpassa dessa spektra lika bra som Band modellen. Ett urval av långa gamma-blixtar har typiska spektra, d.v.s. spektra mycket bredare än svartkropp spektra och KRA kan anpassa dessa spektra väldigt bra. Statistiskt är KRA lika bra som Band modellen och t.o.m. mycket bättre för GRB211211. Jag har också hittat två olika former på spektra som anpassar data lika bra. Först, en breddad svartkropp för ett utflöde i jämvikt och den andra, optiskt grunda shocker för ett utflöde som inte är i jämvikt. För att urskilja mellan dessa lösningar är framtida detektorer med data för lägre energies viktiga. För att sammanfatta, KRA kan reproducera fotosfäriska spektra påverkade av en RMS och dessa spektra can förklara observerade gamma-blixt spektra. Om spektrumet inte är termaliserat kan information om chockens egenskaper hämtas från observerade gamma-blixt spektra.
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Rapid Neutron-Capture Nucleosynthesis from the Births and Deaths of Neutron StarsDesai, Dhruv Ketan January 2023 (has links)
The astrophysical origins of the rapid neutron-capture process (r-process), which gives rise to roughly half of the elements heavier than iron, has remained a mystery for almost 70 years. The likely violent events, which seed the r-process abundances in our solar system and galaxy, remain uncertain to this day. This is in part due to nuclear physics uncertainties associated with the r-process itself, but mainly due to uncertainties in astrophysics modeling. The discovery of the radioactively-powered kilonova emission from the neutron star merger event GW170817 confirmed the violent deaths of neutron stars as one key site of the r-process in the universe. However, other evidence appears to favor an additional r-process channel that more promptly follows star formation in the universe, such as core-collapse supernovae (CCSNe), i.e. the brilliant births of neutron stars.
The two viable sites for the r-process are (1) core-collapse supernovae (CCSNe), which are explosions of massive stars at the end of their lives and (2) compact object mergers, which are violent collisions of stellar remnants formed at the endpoints of stellar evolution.
Chapters 2 and 3 of this dissertation present general relativistic magnetohydrodynamic simulations of one potential r-process site associated with CCSNe: the neutrino-driven wind. These outflows are launched from the hot proto-neutron star (PNS) remnant by neutrino-heating above their surfaces, within seconds after the collapse of a massive star. However, previous work has shown that spherically symmetric winds from non-rotating PNS fail to achieve the requisite conditions for a robust r-process. Chapter 2 explores for the first time the combined effects of rapid rotation and strong gravity of the PNS on the wind properties. Chapter 3 explores the impact of a dynamically strong ordered magnetic field on the properties of non-rotating PNS winds. The wind in both cases is simulated in a controlled environment rather than as a part of a self-consistent global CCSNe simulation, to assess the viability of r-process nucleosynthesis as a function of PNS properties (neutrino energies/luminosities, rotation rate, magnetization).
We find that rapid rotation allows for outflows that are ~10% more neutron-rich in the equatorial region, where the mass loss rate is roughly an order of magnitude higher than that of otherwise equivalent non-rotating models. The birth of very rapidly spinning neutron stars may thus be a site for the production of light r-process nuclei (38 < Z < 47). For PNSs with sufficiently strong magnetic fields (such that magnetic pressure exceeds gas pressure above the PNS surface), we find that equatorial outflows are trapped by the magnetic field in a region near the surface, and therefore receive additional neutrino heating relative to a freely-expanding unmagnetized wind. This allows a modest fraction of the wind material to achieves entropies high enough to synthesize 2nd peak r-process elements via an alpha-rich freeze-out mechanism.
The final chapter explores the interplay between the r-process and the dynamics of compact object merger ejecta. Gravitational wave observatories are expected to detect several additional binary neutron star (BNS) and black hole-neutron star (BHNS) mergers in current and future observing runs, some of which may be accompanied by electromagnetic counterparts such as kilonovae. However, distinguishing more distant BNS from BHNS mergers based on their associated gamma-ray bursts (GRB), has proven tricky.
This chapter presents a calculation of the effects of r-process heating on the dynamics of tidal ejecta from BNS and BHNS mergers. In particular we explore whether late-time fall-back of weakly bound debris created during the merger to the central black hole remnant, can explain the temporally extended X-ray emission observed following several merger GRB on timescales of several seconds to minutes. As a result of the different impact that r-process heating has depending on the composition of the ejecta and the mass of the black hole, a method to differentiate BHNS from BNS mergers, based on their extended X-ray emission, is proposed.
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A Search for Astrophysical Radio Transients at Meter WavelengthsCutchin, Sean 06 December 2011 (has links)
Astrophysical phenomena such as exploding primordial black holes (PBHs), gamma-ray bursts (GRBs), compact object mergers, and supernovae, are expected to produce a single pulse of electromagnetic radiation detectable at the low-frequency end of the radio spectrum. Detection of any of these pulses would be significant for the study of the objects themselves, their host environments, and the interstellar/intergalactic medium. Furthermore, a detection of a radio transient from an exploding PBH could be a signature of an extra spatial dimension, which would drastically alter our perception of spacetime. However, even upper limits on the existence of PBHs, from transient searches, would be important to discussions of cosmology.
We describe a method to carry out an agnostic single-dispersed-pulse search, and apply it to data collected with the Eight-meter-wavelength Transient Array (ETA). ETA is a radio telescope dedicated to searching for transient pulses. It consists of 12 crossed-dipole antenna stands with Galactic-noise-limited performance from 29-47 MHz. There is a vast amount of data collected from an ETA observation. It is therefore greatly beneficial to use a computer cluster, which works in parallel on different parts of a data set, in order to carry out a single-pulse search quickly and efficiently. Each spectrogram in a data set needs to be analyzed individually, without reference to the rest, in order to utilize a computer cluster's capabilities. The data reduction software has been developed for single-dispersed-pulse searches, and is described in this thesis. The data reduction involves sweeping through the collected data with a dedispersion routine assuming a range of dispersion measures. The resulting time series are searched with multiple matched filters for signals above a signal-to-noise threshold.
Applying the single pulse search to ~ 30 hours of ETA data did not yield a compelling detection of an astrophysical signal. However, from ≈ 5 hours of interference-free data we find an observational upper limit to the rate of exploding PBHs of r ≈ 4.8 × 10⁻⁷ pc⁻³ y⁻¹ for a PBH with a fireball Lorentz-factor f = 10<sup>4.3</sup>. This limit is applicable to PBHs in the halo of the Galaxy to distances ≲ 2 kpc, and dispersion measures ≲ 80 pc cm⁻³ . We also find a source-agnostic rate limit ≲ 0.25 events y⁻¹ deg⁻² for pulses of duration < 3 s, and having apparent energy densities ≳ 2.6 × 10⁻²³ J m⁻² Hz⁻¹ at 38 MHz. / Ph. D.
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Limitando a opacidade cósmica com super novas e gamma-ray bursts.COSTA, Felipe Sérvulo Maciel. 07 November 2018 (has links)
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Previous issue date: 2017-11 / Capes / Há cerca de vinte anos, dois grupos de pesquisadores estudaram o brilho aparente das super novas do tipo Ia(SNe Ia) e, de forma independente, descobriram que a expansão atual do universo é acelerada. Esta descoberta lançou a astronomia para a era da
energia escura, componente energética que, dentro da teoria da relatividade geral,é a
responsável pela aceleração cósmica. Porém, a presença de uma opacidade cósmica nos dados de super novas pode imitar o comportamento de uma componente escura. Hoje em dia, embora a aceleração cósmica seja sustentada por outras observações astronômicas, uma possível presença de opacidade nos dados das SNe Ia pode levar a erros nas estimativas de parâmetros cosmológicos. Assim, vários trabalhos na literatura tem investigado a hipótese da transparência do Universo utilizando medidas de distâncias de luminosidade de velas-padrão, como supernovas do tipo Ia (SNeIa) e gamma raybursts (GRBs),e de distâncias obtidas pela taxa de expansão de Hubble H(z), sendo estas últimas independentes da hipótese de transparência cósmica. Nesta dissertação, nós fazemos uma revisão bibliográ fica sobre estes trabalhos, nos quais foram usados dados de SNeIa, GRBse H(z). Novos limites sobre a opacidade foram colocados com os mais recentes dados de GRBse H(z) no contexto do modelo padrão da cosmologia. Os resultados obtidos mostraram que a hipótese da transparência cósmica está em acordo com os dados, porém, os resultados vindos das observações de GRBs, que alcançam z > 9, onde z é o redshift, não excluem a presença de alguma fonte de opacidade com alto grau de con fiança estatística. / About twenty years ago, two groups of researchers studying the apparent brightness
of type Ia super nova e (SNe Ia), independently discovered that the current expansion of
the universe is accelerated. This discovery launched astronomy in to the dark energy
era, an energy component that, with in the theory of general relativity, is responsible for
the cosmic acceleration. However, the presence of a cosmic opacity in SNe Ia data may
mimicthe behavior of a dark component. Now a days, although the cosmic acceleration
is supported by other astronomical observations, a possible presence of opacity in the
SNe Ia data can lead to errors in the cosmological parameter estimates. Thus, several
works in the literature have investigated the universe's transparency hypothesis using
measurement so fluminosity distances of standard candles, suchas SNe Ia and gamma
ray bursts (GRBs), and distances obtained of the cosmic expansion rate H(z). These last
ones being independent of the cosmic transparency hypothesis. In this dissertation, we
make a bibliographical review on these works and new limits on opacity were placed with
the latest data of GRB sand H(z) in the context of the standard model. We have found
that the cosmic transparency hypothesis is in agreement with the data, but the results
from the observations of GRBs, which reach z > 9, where z is the it red shift, do not
exclude the presence of some source of opacity with a high degree of statistical con dence.
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Comprendre la physique des sursauts gamma grâce aux corrélations dans les données / Understanding the physics behind the correlations of Gamma-ray bursts dataBardho, Onelda 10 March 2016 (has links)
Les Sursauts de Rayonnement Gamma (GRBs) sont des flashs émanant du cosmos qui sont classés en deux groupes : les longs/doux et les courts/durs. Le lancement du satellite Swift a ouvert une nouvelle ère dans la recherche sur les GRBs. Cette thèse présente une étude détaillée du GRB 141221A qui montre une forte et inhabituelle hausse des valeurs des courbes de lumière dans le domaine optique lors de l'émission rémanente alors que dans le domaine des rayons X ces valeurs sont plus normales. GRB 141221A est un des GRBs qui mettent à l'épreuve les modèles car il exclut tout vent stellaire du progéniteur. Un regroupement des courbes de lumière dans le domaine X lors de l'émission rémanente GRBs a été observé avant le lancement de Swift. Cette classification a été débattue après le lancement de Swift. Nous avons construit un échantillon de 254 GRBs qui montre un éparpillement des distributions du flux à un jour. Cette distribution a été normalisée avec un décalage vers le rouge de 1. Nous avons investigué ce problème selon trois directions: un problème instrumental, un problème de calibration des données ou l'absence de regroupement. Coté instrument, le problème pourrait être observationnel, nous avons en effet observé des effets saisonniers durant les solstices et les équinoxes. Coté calibration des données, un tel problème pourrait avoir une influence sur les résultats de l'étude. La comparaison entre analyse manuelle et automatique des données telle que disponible sur le dépôt Swift-XRT montre de sérieux aléas sur les résultats. Les cas où l'analyse manuelle est judicieuse sont exposés. La dernière possibilité de l'absence de regroupement pourrait être un effet de sélection. / GRBs are ashes of gamma-rays coming from cosmos. They are one of the most mysteriousevents we have been able to observe since their discovery. GRBs are classified into two groups: long/soft GRBs and short/hard GRBs. Their emission mechanism consists of two phases: prompt emission and afterglow emission. The launch of the Swift satellite opened a New Era in the GRBs research. Swift is able to provide accurate position for more GRBs than previous missions, thanks to its fast capabilities of slewing. Furthermore, the Swift shows that GRBs have a canonical behaviour for the X-ray afterglow light curves. The data analysis process remains the key point of GRBs studies. I present a detailed study of the peculiar GRB 141221A at different wavelengths. GRB 141221A shows an unusual steep rise in the optical light curve of the afterglow. The broad band spectral energy distribution, taken near the maximum of the optical emission, presents either a thermal component or a behaviourbreak. This burst displays unusual feature in the optical band, whereas the X-ray data is more common. GRB 141221A is one of the challenging bursts that excludes a stellar wind from the progenitor of the GRBs. A clustering in the X-ray afterglow light curves was observed before the launch of the Swift satellite. This feature has been debated after the launch of the Swift. We have built a sample which consists of 254 GRBs that shows a scattering of the data for the flux distribution at one day. This distribution was investigated with a normalization of light curves at redshift one. We have investigated the problem into three different directions
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Binaires compactes : modèles de populations, détection multi-messagers et cosmologie / Compact binaries : models of populations, multi-messenger detection and cosmologyMeacher, Duncan 08 September 2015 (has links)
Je présente ma thèse sur l'analyse des ondes gravitationnelles dans les deux domaines suivants. Pour le premier il s'agit de vérifier que les collaborations LIGO et Virgo sont prêtes pour la détection d'un fond gravitationnel stochastique astrophysique pendant l'ère des détecteurs avancés qui va démarrer à l'été 2015. Pour le deuxième il s'agit de poursuivre l'étude du potentiel scientifique, notamment pour l'astrophysique et la cosmologie, d'un détecteur de troisième génération, le Einstein Telescope. Dans les deux cas, j'utilise des "mock data and science challenges" qui consistent à simuler Les données des détecteurs gravitationnels contenant un grand nombre de sources distribuées de façon réalistes dans l'espace des paramètres. / Here I present my thesis investigating gravitational-wave data analysis in the following two areas. The first is to test the readiness of the LIGO-Virgo collaborations to the advanced detector era, which will begin in the summer of 2015, to make a detection of an astrophysical stochastic gravitational-wave background. The second is to continue an investigation into the science potential of a conceived, third generation gravitational-wave detector, the Einstein Telescope, in terms of astrophysics and cosmology. Both of these are conducted with the use of mock data and science challenges which consists of the production of expected gravitational-wave detector data, containing a large number of sources, that are simulated using realists distributions.
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La détection des sursauts gamma par le télescope ECLAIRs pour la mission spatiale SVOM / Detection of Gamma-Ray Bursts with the ECLAIRs instrument onboard the space mission SVOMAntier-Farfar, Sarah 29 November 2016 (has links)
Les sursauts gamma sont des événements fascinants de par leur origine longtemps restée mystérieuse, leur apparition imprévisible dans le ciel, et la formidable énergie qu'ils libèrent sous forme de bouffées de rayonnement gamma. Découverts fortuitement au début des années 1970, ils se traduisent par un intense flash de rayons gamma de brève durée (de quelques ms à quelques min), appelé émission prompte, suivi d'une émission longue, appelée rémanence, qui décroît rapidement, en émettant depuis les rayons X jusqu'au domaine radio. L'origine des sursauts gamma est encore largement discutée mais ces phénomènes extrêmes sont très vraisemblablement associés à la formation de nouveaux trous noirs stellaires. Mon sujet de thèse se situe au coeur de la mission sino-française SVOM dont le lancement du satellite est prévu en 2021, qui scrutera le ciel pour observer les sursauts avec une précision inégalée, associant observations spatiales et terrestres. Mon travail concerne l'instrument principal de la mission, le télescope spatial ECLAIRs. Il s'agit d'une caméra à masque codé sensible aux rayons X et gamma de basse énergie, en charge de la détection et de la localisation de l'émission prompte des sursauts. Durant mon travail de thèse, j'ai travaillé sur les performances scientifiques de l'instrument ECLAIRs et j'ai en particulier estimé le nombre de sursauts qui seront détectés et leurs caractéristiques. Pour cela, j'ai mis en place des simulations de performances utilisant les prototypes des algorithmes de détection embarqués combinés au modèle de l'instrument ECLAIRs. Les données en entrée des simulations comportent un bruit de fond simulé, et une population synthétique de sursauts gamma générée à partir de catalogues existants issus des observations des missions antérieures (CGRO, HETE-2, Swift et Fermi). Mon étude a permis d'estimer finement l'efficacité de détection d'ECLAIRs et prédit un taux de sursauts attendu par ECLAIRs entre 40 et 70 sursauts par an. Par ailleurs, mon travail a montré qu'ECLAIRs sera particulièrement sensible à une population de sursauts très riches en rayons X, population encore mal connue. Ma thèse présente plusieurs autres études complémentaires portant sur la performance de localisation, le taux de fausses alertes et les caractéristiques des déclenchements des algorithmes. Enfin, j'ai proposé deux nouvelles méthodes originales de détection de sursauts dont les résultats préliminaires présentés dans ma thèse sont très encourageants. Ils montrent que la sensibilité d'ECLAIRs aux sursauts courts (population d'intérêt particulier en raison de son lien attendu avec les ondes gravitationnelles) peut être encore améliorée. / Discovered in the early 1970s, gamma-ray bursts (GRBs) are amazing cosmic phenomena appearing randomly on the sky and releasing large amounts of energy mainly through gamma-ray emission. Although their origin is still under debate, they are believed to be produced by some of the most violent explosions in the Universe leading to the formation of stellar black-holes. GRBs are detected by their prompt emission, an intense short burst of gamma-rays (from a few millisecondes to few minutes), and are followed by a lived-afterglow emission observed on longer timescales from the X-ray to the radio domain. My thesis participates to the developement of the SVOM mission, which a Chinese-French mission to be launched in 2021, devoted to the study of GRBs and involving space and ground instruments. My work is focussed on the main instrument ECLAIRs, a hard X-ray coded mask imaging camera, in charge of the near real-time detection and localization of the prompt emission of GRBs. During my thesis, I studied the scientific performances of ECLAIRs and in particular the number of GRBs expected to be detected by ECLAIRs and their characteristics. For this purpose, I performed simulations using the prototypes of the embedded trigger algorithms combined with the model of the ECLAIRs instrument. The input data of the simulations include a background model and a synthetic population of gamma-ray bursts generated from existing catalogs (CGRO, HETE-2, Fermi and Swift). As a result, I estimated precisely the ECLAIRs detection efficiency of the algorithms and I predicted the number of GRBs to be detected by ECLAIRs : 40 to 70 GRBs per year. Moreover, the study highlighted that ECLAIRs will be particularly sensitive to the X-ray rich GRB population. My thesis provided additional studies about the localization performance, the rate of false alarm and the characteristics of the triggers of the algorithms. Finally, I also proposed two new methods for the detection of GRBs.The preliminary results were very promising and demonstrate that the sensitivity of ECLAIRs to the short GRBs (an interesting population due to the predicted association with gravitational waves) could be improved further.
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Etude et optimisation des performances de l'instrument MXT, télescope X à micro-canaux, embarqué à bord de la mission spatiale d'astronomie SVOM / Study and optimization of the MXT instrument, microchannel X-ray telescope onboard the SVOM space missionGosset, Laura 04 February 2019 (has links)
SVOM est une mission spatiale franco-chinoise qui sera lancée à la fin de l’année 2021. Son objectif est d’étudier les sursauts gamma et autres sources transitoires du ciel X et gamma. Les sursauts gamma sont des explosions cosmiques brèves et très énergétiques permettant leurs détections à des distances extrêmes. Ils apparaissent de manière aléatoire sur tout le ciel et émettent de la radiation dans une large gamme de longueurs d’ondes, allant de l’émission en infrarouge jusqu’aux rayons gamma. SVOM, qui évoluera en orbite basse autour de la Terre, sera composé de quatre instruments, sensibles du domaine visible aux rayons gamma, et sera couplé à des télescopes situés sur Terre qui effectueront des observations complémentaires dans les longueurs d’ondes allant du visible à de l’infrarouge. Le travail que je présente dans cette thèse est basé sur l’étude des performances du télescope MXT, dont l’optique est inspirée du principe de fonctionnement des “yeux des langoustes”. Elle sera mise en place pour la première fois dans le cadre de télescopes X, nécessitant donc de comprendre la réponse de cette optique. MXT est chargé d’observer, la contrepartie qui suit les sursauts gamma, dite émission rémanente, dans la gamme des rayons X entre 0,2 et 10 keV. Il joue un rôle clé dans la localisation précise de ces sources astrophysiques afin de transmettre, en temps réel, leurs positions aux télescopes situés au sol, qui observeront à leur tour, rapidement et précisément, le phénomène. Au cours de mon travail de thèse, j’ai mis en place un simulateur d’observation de MXT qui m’a permis d’estimer et d’étudier les performances attendues de l’instrument au cours de la mission. J’ai également développé des algorithmes de localisation qui seront implémentés à bord du satellite. Ceux-ci m’ont ensuite permis de tester les capacités de localisation de MXT à partir d’une base de données des rémanences de sursauts gamma et de montrer que 50% de ces rémanences seront localisées plus précisément que la minute d’arc. J’ai enfin appliqué une partie de mes modélisations numériques dans le cas de sources d’ondes gravitationnelles afin d’évaluer la détection des contreparties X d’étoiles à neutrons binaires. / SVOM is a Sino-French space mission to be launched at the end of 2021. Its objective is the study of gamma-ray bursts (GRBs) and other transient high energy sources. These GRBs are very powerful cosmic explosions that can be detected at extreme distances. They appear randomly on all the sky and emit radiation in a wide wavelength range, from the infrared emission to gamma rays. SVOM space mission will shed new light on the physical phenomena associated to GRBs by detecting and observing them in real time over a wide energy range. The satellite, which will be injected on a low Earth orbit, will carry four instruments sensitive from the visible to the gamma-ray domain. Ground based telescopes will complement the space borne ones and will allow for follow-up observations from the visible to the infrared band. The MXT instrument, whose optics are based on the “lobster eyes” principle, will observe GRBs soft X-rays counterparts (afterglows) between 0.2 and 10 keV. This optics will be used for the first time for an X-ray telescope which means to characterize this optics. MXT will play a key role in the localization of these astrophysical sources that will be transmitted, in real time, to ground based instruments allowing for fast and precise observations. During my thesis, I developed an MXT observation simulator in order to predict the performances of the instrument during the mission. I also developed localization algorithms to be implemented on board the SVOM satellite and made use of the state of the art knowledge about X-ray afterglows in order to predict the localization capabilities of MXT. I demonstrated thaht 50% of these afterglows will be localized with a better precision than the arc-minute. I finally applied my simulation tools in the case of gravitational wave sources and, in particular, to assess the capabilities of MXT to observe bright X-ray counterparts of binary neutron star mergers.
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Investigation of the Mass-Metallicity Relation of GRB Host Galaxies at z ~ 4.7Sears, Huei M. January 2020 (has links)
No description available.
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