Global ETD Search

21	VERITAS, 1ES 1218 + 30.4 and the extragalactic background light Valcárcel, Luis, January 1900 (has links) Thesis ( Ph.D.). / Written for the Dept. of Physics. Title from title page of PDF (viewed 2009/06/11). Includes bibliographical references.
22	Détection, localisation et étude des propriétés spectrales de sursauts gamma observés à haute énergie avec l'expérience Fermi. / Detection, localization and spectral analyses of gamma-ray bursts observed at high energies with the Fermi space telescope. Pelassa, Véronique 13 December 2010 (has links) Les sursauts gamma sont des sources astrophysiques parmi les plus brillantes du ciel. Dans le modèle standard actuel, leur émission prompte (X et gamma) est due à des particules chargées accélérées au sein de jets relativistes émis à la formation de trous noirs de masses stellaire. L'émission rémanente observée de la radio aux X serait due à l'interaction de ces jets avec le milieu interstellaire. Le LAT, détecteur à création de paire du télescope spatial Fermi, permet depuis juin 2008 l'étude du ciel gamma de 20 MeV à plus de 300 GeV avec des performances inégalées. Le GBM, détecteur de sources transitoires de Fermi (8 keV à 40 MeV) a observé ~450 sursauts gamma, dont ~18 ont été observés jusqu'au domaine du GeV. Une localisation précise de ces sursauts et la synergie de Fermi avec les autres observatoires permettent l'étude des rémanences associées et une meilleure interprétation des observations. L'étude de sursauts gamma de 8 keV au domaine du GeV est présentée. Les localisations obtenues avec le LAT sont étudiées ainsi que leurs erreurs. Des analyses spectrales des émissions promptes combinant les données du GBM et du LAT sont exposées, ainsi que leur interprétation. Une analyse alternative basée sur une sélection relâchée des données LAT est présentée et caractérisée. L'utilisation des événements d'énergies inférieures à 100 MeV améliore l'analyse temporelle et spectrale des émissions promptes. La recherche d'émission gamma prolongée est présentée, ainsi que l'étude de l'émission rémanente de GRB 090510 observé des UV au GeV par Fermi et Swift. Enfin, un modèle d'émission prompte par les chocs internes, développé à l'IAP, est comparé aux observations de Fermi. / Gamma-Ray Bursts (GRB) are among the brightest gamma-ray sources in the sky. The current standard framework associates their prompt gamma-ray emission to charged particles accelerated in relativistic jets issued by newly-formed stellar-mass black holes. The radio to X-ray afterglow emission is due to the interaction between these jets and the interstellar medium.The LAT, pair-creation instrument onboard Fermi gamma-ray space telescope, performs unprecedented observation of the gamma-ray sky at energies of 20 MeV to over 300 GeV since its launch in june 2008. Fermi's transient sources detector, GBM, observed prompt emissions of ~450 GRB between 8 keV and 40 MeV. ~18 of these GRB were also studied up to GeV energies with the LAT. Accurate GRB localizations and Fermi's synergy with other observatories allows the study of GRB afterglows, and therefore a better interpretation of these observations.The analyses of GRB emissions between 8 keV to GeV energies is presented here. Localizations based on LAT data and their biases are studied. Spectral analyses of combined GBM and LAT data are shown, and their theoretical interpretations explained.An alternative analysis based on a relaxed selection of LAT data is presented and fully characterized. It allows to recover and use low-energy LAT statistics in temporal and spectral analyses of GRB prompt emission.Searches for long-lived high-energy emission from GRB are presented. The analysis of GRB 090510 afterglow emission from eV to GeV energies is described.Finally, Fermi bright GRB prompt emissions are compared to an internal shock model developed at IAP. Astronomie gamma Sursauts gamma Analyse statistique Gamma-ray astronomy Gamma-ray bursts Statistical data analysis
23	Recherche de nouveaux bosons légers en astronomie de haute énergie / Search for new light bosons in high energy astronomy Wouters, Denis 30 June 2014 (has links) L'astronomie de haute énergie se concentre sur l'étude des phénomènes les plus violents de l'univers à partir d'observations dans une gamme d'énergie allant des rayons X aux rayons gammas de très hautes énergies (1 keV - 100 TeV). Ces phénomènes incluent par exemple les explosions de supernovae et leurs vestiges, les pulsars et les nébuleuses de vent de pulsar ou encore la formation de jets ultrarelativistes au niveau des noyaux actifs de galaxie. Leur compréhension fait appel à des processus de physique des particules bien connus qui seront décrits dans cette thèse. Par l'intermédiaire de photons de haute énergie, l'étude de ces phénomènes de haute énergie ouvre donc une fenêtre originale pour la recherche de physique au delà du modèle standard. Les concepts relatifs à l'émission et la propagation de photons de haute énergie sont introduits dans cette thèse et appliqués à l'étude de l'émission de sources extragalactiques ainsi que du fond de lumière extragalactique, affectant la propagation des photons de haute énergie dans l'univers. Dans le cadre de cette thèse, ces sources extragalactiques de photons de haute énergie sont observées afin de rechercher de nouveaux bosons légers, tels que ceux appartenant à la famille des particules de type axion (PTA). Les bases théoriques décrivant cette famille de particules sont présentées, ainsi que la phénoménologie associée. Notamment, en raison de leur couplage à deux photons, ces particules ont la propriété d'osciller avec des photons en présence de champ magnétique externe. Une nouvelle signature de la présence de telles oscillations dans des champs magnétiques turbulents, sous la forme d'irrégularités stochastiques dans le spectre en énergie, est étudiée et discutée. Cette signature est appliquée à la recherche de PTA avec le réseau de télescopes HESS, permettant d'obtenir pour la première fois des contraintes sur ces modèles à partir d'observations en astronomie gamma. La recherche de la même signature dans des observations en rayons X permet d'améliorer les contraintes actuelles pour les PTA de très basse masse et l'extension de ces contraintes à des modèles de modification de la gravité comme explication de la nature de l'énergie noire est également évoquée. Enfin, la recherche de PTA avec l'instrument d'astronomie gamma du futur, CTA, est discutée; en particulier, une nouvelle observable est proposée qui tire partie du grand nombre de sources attendu avec cet instrument. / High-Energy astronomy studies the most violent phenomena in the universe with observations in a large spectrum of energies ranging from X rays to very high energy gamma rays (1 keV - 100 TeV). Such phenomena could be for instance supernovae explosions and their remnants, pulsars and pulsar wind nebulae or ultra relativistic jets formation by active galactic nuclei. Understanding these phenomena requires to use well-known particle physics processes. By means of high energy photons, studying such phenomena enables one to search for physics beyond the standard model. Concepts regarding the emission and propagation of high-energy photons are introduced and applied to study their emission by extragalactic sources and to constrain the extragalactic background light which affects their propagation. In this thesis, these high-energy extragalactic emitters are observed in order to search for new light bosons such as axion-like particles (ALPs). The theoretical framework of this family of hypothetical particles is reviewed as well as the associated phenomenology. In particular, because of their coupling to two photons, ALPs oscillate with photons in an external magnetic field. A new signature of such oscillations in turbulent magnetic fields, under the form of stochastic irregularities in the source energy spectrum, is introduced and discussed. A search for ALPs with the HESS telescopes with this new signature is presented, resulting in the first constraints on ALPs parameters coming from high-energy astronomy. Current constraints on ALPs at very low masses are improved by searching for the same signature in X-ray observations. An extension of these constraints to scalar field models for modified gravity in the framework of dark energy is then discussed. The potential of the search for ALPs with CTA, the prospected gamma-ray astronomy instrument, is eventually studied; in particular, a new observable is proposed that relies on the high number of sources that are expected to be discovered with this instrument. Axions Astronomie gamma Noyaux actifs de galaxies Axions Gamma-ray astronomy Active galactic nuclei
24	Observations of supernova remnants at very high energies with VERITAS Wilcox, Patrick Dean 01 August 2019 (has links) The constant flux of cosmic rays that bombard Earth from within our own galaxy are understood to come from both shell-type supernova remnants and pulsar wind nebulae (PWNe). Multiwavelength study of these objects can help us to understand what types of particles are accelerated, and gamma-ray emission is key to understanding the highest energy cosmic rays. In this thesis, I analyze and interpret observations made with the Very Energetic Radiation Imaging Telescope Array System (VERITAS), a gamma-ray telescope located in Southern Arizona. LS 5039 and HESS J1825-137 occupy the same field of view on the sky and were observed for about 8 hours with VERITAS. LS 5039 is a gamma-ray binary, and the observations supports theories that the compact object hosts a PWN which is continuously interacting with the nearby star. HESS J1825-137 is a very extended PWN with an extent of diameter greater than 1 degree on the sky. Using the VERITAS observations, I am able to measure the radial profile and compare the gamma-ray luminosity to other PWN. DA 495, a "Crab-like" PWN with unusually strong magnetic fields, was observed for about 70 hours with VERITAS. In this study, results are combined with radio and X-ray spectral information to allow for detailed astrophysical modeling of the region. This broadband spectral modeling places constraints on the properties of the particle population in this PWN and allows for both leptonic and hadronic emission scenarios to be evaluated. Hadronic scenarios instil doubt on the pure PWN interpretation and favor a previously undetected shell-type remnant being present. gamma-ray astronomy particle acceleration pulsar wind nebula supernova remnants Physics
25	Advancements in Very-High-Energy Gamma-Ray Astronomy with Applications to the Study of Cosmic Rays Petrashyk, Andrii January 2019 (has links) This work aims to contribute to the study of the origins of cosmic rays, and broadly, to the advancement of both data analysis methods and instrumentation for very-high-energy γ-ray astronomy. First, reviewing the state of γ-ray astronomy, we show how gains in sensitivity can be achieved through sophisticated data analyses and improved instrumental designs. We then develop such an improved analysis method for the Very Energetic Radiation Imaging Telescope Array System (VERITAS) by combining Image Template Method (ITM) with Boosted Decision Trees (BDT), and study its performance, attaining a 30-50% improvement in integral sensitivity over the instrument’s standard analysis. Systematic issues in spectral reconstruction that the analysis displays are resolved satisfactorily by imposing a more stringent condition on the selection of its energy threshold. We employ the newly developed analysis to measure the γ-ray energy spectrum of the starburst galaxy M82, and combining our result with a measurement from the Fermi Large Area Telescope (Fermi-LAT), we find that a single power law fits the spectrum well between 100 GeV and 10 TeV, with no evidence for a spectral break or a cutoff. We conclude that this is in line with the current understanding that M82 is not a good proton calorimeter. Finally, we detail the design, implementation, and performance of the optical alignment system of the prototypeSchwarzschild-Couder Telescope (pSCT) for the Cherenkov Telescope Array (CTA), a novel two-mirror design that addresses many shortcomings of current instruments. Astrophysics Cosmic rays Gamma ray astronomy Gamma rays--Measurement Gamma rays--Data processing
26	Search for ultra high energy radiation from astrophysical sources / Rishi Meyhandan. Meyhandan, Rishi January 1994 (has links) Bibliography: p. 157-167. / ii, 180 p. : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Presents results of searches made with the Buckland Park and SUGAR data sets for Ultra High Energy gamma-ray emission from certain astrophysical objects. / Thesis (Ph.D.)--University of Adelaide, Dept. of Physics and Mathematical Physics, 1994 523.019/722 20 Gamma ray astronomy. Gamma ray sources. Cosmic ray showers.
27	The development of a hardware random number generator for gamma-ray astronomy / R.C. Botha Botha, Roelof Cornelis January 2005 (has links) Pulsars, as rotating magnetised neutron stars got much attention during the last 40 years since their discovery. Observations revealed them to be gamma-ray emitters with energies continuing up to the sub 100 GeV region. Better observation of this upper energy cut-off region will serve to enhance our theoretical understanding of pulsars and neutron stars. The H-test has been used the most extensively in the latest periodicity searches, whereas other tests have limited applications and are unsuited for pulsar searches. If the probability distribution of a test statistic is not accurately known, it is possible that, after searching through many trials, a probability for uniformity can be given, which is much smaller than the real value, possibly leading to false detections. The problem with the H-test is that one must obtain the distribution by simulation and cannot do so analytically. For such simulations, random numbers are needed and are usually obtained by utilising so-called pseudo-random number generators, which are not truly random. This immediately renders such generators as useless for the simulation of the distribution of the H-test. Alternatively there exists hardware random number generators, but such devices, apart from always being slow, are also expensive, large and most still don't exhibit the true random nature required. This was the motivation behind the development of a hardware random number generator which provides truly random U(0,l) numbers at very high speed and at low cost The development of and results obtained by such a generator are discussed. The device delivered statistically truly random numbers and was already used in a small simulation of the H-test distribution. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2005. H-test Pulsar searches Periodicity searches Gamma-ray astronomy Random number generator True randomness
28	The development of a hardware random number generator for gamma-ray astronomy / R.C. Botha Botha, Roelof Cornelis January 2005 (has links) Pulsars, as rotating magnetised neutron stars got much attention during the last 40 years since their discovery. Observations revealed them to be gamma-ray emitters with energies continuing up to the sub 100 GeV region. Better observation of this upper energy cut-off region will serve to enhance our theoretical understanding of pulsars and neutron stars. The H-test has been used the most extensively in the latest periodicity searches, whereas other tests have limited applications and are unsuited for pulsar searches. If the probability distribution of a test statistic is not accurately known, it is possible that, after searching through many trials, a probability for uniformity can be given, which is much smaller than the real value, possibly leading to false detections. The problem with the H-test is that one must obtain the distribution by simulation and cannot do so analytically. For such simulations, random numbers are needed and are usually obtained by utilising so-called pseudo-random number generators, which are not truly random. This immediately renders such generators as useless for the simulation of the distribution of the H-test. Alternatively there exists hardware random number generators, but such devices, apart from always being slow, are also expensive, large and most still don't exhibit the true random nature required. This was the motivation behind the development of a hardware random number generator which provides truly random U(0,l) numbers at very high speed and at low cost The development of and results obtained by such a generator are discussed. The device delivered statistically truly random numbers and was already used in a small simulation of the H-test distribution. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2005. H-test Pulsar searches Periodicity searches Gamma-ray astronomy Random number generator True randomness
29	Crab flare observations with H.E.S.S. phase II Balzer, Arnim January 2014 (has links) The H.E.S.S. array is a third generation Imaging Atmospheric Cherenkov Telescope (IACT) array. It is located in the Khomas Highland in Namibia, and measures very high energy (VHE) gamma-rays. In Phase I, the array started data taking in 2004 with its four identical 13 m telescopes. Since then, H.E.S.S. has emerged as the most successful IACT experiment to date. Among the almost 150 sources of VHE gamma-ray radiation found so far, even the oldest detection, the Crab Nebula, keeps surprising the scientific community with unexplained phenomena such as the recently discovered very energetic flares of high energy gamma-ray radiation. During its most recent flare, which was detected by the Fermi satellite in March 2013, the Crab Nebula was simultaneously observed with the H.E.S.S. array for six nights. The results of the observations will be discussed in detail during the course of this work. During the nights of the flare, the new 24 m × 32 m H.E.S.S. II telescope was still being commissioned, but participated in the data taking for one night. To be able to reconstruct and analyze the data of the H.E.S.S. Phase II array, the algorithms and software used by the H.E.S.S. Phase I array had to be adapted. The most prominent advanced shower reconstruction technique developed by de Naurois and Rolland, the template-based model analysis, compares real shower images taken by the Cherenkov telescope cameras with shower templates obtained using a semi-analytical model. To find the best fitting image, and, therefore, the relevant parameters that describe the air shower best, a pixel-wise log-likelihood fit is done. The adaptation of this advanced shower reconstruction technique to the heterogeneous H.E.S.S. Phase II array for stereo events (i.e. air showers seen by at least two telescopes of any kind), its performance using MonteCarlo simulations as well as its application to real data will be described. / Das H.E.S.S. Experiment misst sehr hochenergetische Gammastrahlung im Khomas Hochland von Namibia. Es ist ein sogenanntes abbildendes atmosphärisches Cherenkov-Teleskopsystem welches in der 1. Phase, die im Jahr 2004 mit der Datennahme begann, aus vier identischen 13 m Spiegelteleskopen bestand. Seitdem hat sich H.E.S.S. als das erfolgreichstes Experiment in der bodengebundenen Gammastrahlungsastronomie etabliert. Selbst die älteste der mittlerweile fast 150 entdeckten Quellen von sehr hochenergetischer Gammastrahlung, der Krebsnebel, fasziniert immernoch Wissenschaftler mit neuen bisher unbekannten und unerwarteten Phänomenen. Ein Beispiel dafür sind die vor kurzem entdeckten sehr energiereichen Ausbrüche von hochenergetischer Gammastrahlung. Bei dem letzten deratigen Ausbruch des Krebsnebels im März 2013 hat das H.E.S.S. Experiment für sechs Nächte simultan mit dem Fermi-Satelliten, welcher den Ausbruch entdeckte, Daten genommen. Die Analyse der Daten, deren Ergebnis und deren Interpretation werden im Detail in dieser Arbeit vorgestellt. Während dieser Beobachtungen befand sich ein neues 24 m × 32 m großes Spiegelteleskop, das H.E.S.S. II- Teleskop, noch in seiner Inbetriebnahme, trotzdem hat es für eine dieser sechs Nächte an der Datennahme des gesamten Teleskopsystems teilgenommen. Um die Daten rekonstruieren und analysieren zu können, mussten die für die 1. Phase des Experiments entwickelten Algorithmen und die Software des H.E.S.S.- Experiments angepasst werden. Die fortschrittlichste Schauerrekonstruktionsmethode, welche von de Naurois und Rolland entwickelt wurde, basiert auf dem Vergleich von echten Schauerbildern, die mit Hilfe der Cherenkov-Kameras der einzelnen Teleskope aufgenommen wurden, mit Schauerschablonen die mit Hilfe eines semianalytischen Modells erzeugt wurden. Das am besten passende Bild und damit auch alle relevanten Schauerparameter, wird mit Hilfe einer pixelweisen Loglikelihood-Anpassung ermittelt. Die nötigen Änderungen um Multiteleskopereignisse, welche vom heterogenen H.E.S.S. Phase II Detektor gemessen wurden, mit Hilfe dieser fortschrittlichen Schauerrekonstruktionsmethode analysieren zu können, sowie die resultierenden Ergebnisse von MonteCarlo-Simulationen, als auch die Anwendung auf echte Daten, werden im Rahmen dieser Arbeit präsentiert. Gammastrahlungsastronomie Rekonstruktionsmethoden Datenanalyse Krebsnebel gamma-ray astronomy reconstruction methods data analysis Crab Nebula Physics
30	Multiwavelength Studies Of Gamma-Ray Emitting Radio Galaxies / Multi-Wellenlängen Studien von Gammastrahlung emittierende Radiogalaxien Saxena, Sheetal January 2020 (has links) (PDF) Although the contribution to the Isotropic Gamma-Ray Background (IGRB) from unresolved extragalactic objects has been studied for many years, its exact composition and origin are as of yet unknown. It is suspected that diffuse processes such as dark matter annihilation contribute to the total IGRB, as well as unresolved gamma-ray emission from Active Galactic Nuclei (AGN), including radio galaxies. Radio galaxies are a source class that emit strongly at radio wavelengths, some of which have also been detected at gamma-ray wavelengths by the Fermi Large Area Telescope (Fermi-LAT), and by very high energy gamma-ray Cherenkov telescopes. It is thought that due to the orientation of their jets, radio galaxies are detected less numerously at gamma-ray energies than blazars. Furthermore, only a small number of radio galaxies have been detected at gamma-ray energies though it is considered that others do as well. It is for these reasons that gamma-ray emitting radio galaxies, an interesting and elusive class of objects, are selected for investigation in this work. In order to reach the goal of better understanding diffuse processes, it is necessary to model the radio galaxy spectral energy distributions (SEDs). As AGN emission is variable with respect to time, it is critical to use simultaneously collected observations. Calculation of the SED based on simultaneous, multiwavelength data across the electromagnetic spectrum produces a reasonably accurate representation of the state of an object in a given time range. The gamma-ray emitting radio galaxies M 87, NGC 1275, Pictor A, and Centaurus A are selected here based on having been detected in very high energy gamma-rays by Cherenkov telescopes, as well as in other wavelengths. A uniquely consistent analysis approach is applied, in which each radio galaxy is analyzed the same way using simultaneously collected data. This approach sets it apart from other studies. Fermi-LAT raw data for each source in the sample is analyzed in time ranges which directly overlap the very high energy gamma-ray Cherenkov observations, as well as several other wavelength ranges. A synchrotron self-Compton (SSC) model is applied, which provides accurate treatment of synchrotron and inverse-Compton processes occurring in the jets of AGN, while estimating physical characteristics of the source. It is found that the spectra of M 87, NGC 1275, Pictor A, and Centaurus A can be well described by the same SSC model, producing values for the physical characteristics such as the doppler factor and magnetic field, which are relatively consistent with each other. In order to characterize the diffuse emission from dark matter self-annihilation, the radio galaxy SEDs are also fit with a dark matter model, resulting in an estimated dark matter particle mass of around 4.7 TeV which lies within predicted ranges. The highly dense regions near the black holes of AGN provide the optimal conditions for detecting these signatures. It is also found here that discrepancies between the expected emission and the observed emission in the spectra of some radio galaxies can be explained using the combined SSC and dark matter model. As emission from dark matter annihilation is expected to remain steady with respect to time, a key feature of this work is the novelty of the combined SSC and dark matter model, and the finding that dark matter characteristics may be revealed through similar multiwavelength analyses during future low emission states of the AGN. The radio galaxy sample is then extended to include all gamma-ray emitting radio galaxies detected by the Fermi-LAT, and a calculation of the core radio, total radio, and gamma-ray luminosities is followed through. A future step in extending this work would be to estimate the gamma-ray luminosity function of radio galaxies and their percent contribution to the total IGRB, based on the widely agreed upon assumption that a reasonable estimate of the gamma-ray luminosity function of a population can be attained by appropriately scaling its radio luminosity function, as gamma-ray luminosities and radio luminosities are strongly linearly correlated. This work has also provided the basis for such a calculation by outlining the theory and initial steps. It is the hope that the vast scope of the gathered data, its simultaneity, and the use of consistent analysis methods across the sample, will provide an improved foundation for a future calculation of the contribution of this population to the IGRB, as well as encourage stricter requirements for multiwavelength studies. / Der Ursprung, sowie die exakte Zusammensetzung des isotropischen Gammastrahlen-Hintergrunds (IGRB), sind trotz jahrelanger Studien über den Einfluss unaufgelöster extragalaktischer Objekte, nicht abschließend geklärt. Es wird für möglich gehalten, dass diffuse Prozesse, wie z.B. die Annihilation dunkler Materie, sowie bisher nicht detektierte Gammastrahlen-Emission aus aktiven Galaxiekernen (AGN), wie zum Beispiel Radiogalaxien, dazu beitragen. Radiogalaxien gehören zu der Gattung der Quellen, die stark im Radiowellenbereich emittieren. Einige dieser Galaxien wurden auch im Wellenlängenbereich von Gammastrahlung mittels des Fermi Large Area Telescope (Fermi-LAT) und für sehr energiereiche Gammastrahlung mittels Cherenkov-Detektoren nachgewiesen. Es wird davon ausgegangen, dass die kleinere Anzahl an nachgewiesenen Radiogalaxien im Gammastrahlenbereich, verglichen mit der Anzahl an nachgewiesenen Blazaren, auf die Orientierung ihrer Jets zurückzuführen ist. Des Weiteren wurde bisher nur eine kleine Anzahl an Radiogalaxien im Energiebereich der Gammastrahlung nachgewiesen, obwohl davon auszugehen ist, dass der Nachweis auch für weitere Galaxien möglich ist. Aus diesen Gründen werden Gammastrahlung emittierende Radiogalaxien, eine interessante und schwer auffindbare Klasse an Objekten, zur Untersuchung im Rahmen dieser Arbeit ausgewählt. Zur Verbesserung des Verständnisses diffuser Prozesse ist eine Modellierung der spektralen Energiedichteverteilung (SED) notwendig. Da die Emission von AGN zeitlich variiert, ist es wichtig simultan aufgezeichnete Daten für die Analyse zu verwenden. Die Berechnung der spektralen Energiedichteverteilung, basierend auf zeitgleich aufgezeichneten Daten für eine Vielzahl an Wellenlängen des elektromagnetischen Spektrums, liefert eine hinreichend genaue Beschreibung des Zustandes eines Objektes innerhalb eines gegebenen Zeitraumes. Diese Arbeit konzentriert sich auf die Gammastrahlung emittierenden Radiogalaxien M 87, NGC 1275, Pictor A und Centaurus A, da diese mittels Cherenkov-Teleskopen im Bereich hochenergetischer Gammastrahlung, sowie auch in anderen Wellenlängenbereichen, nachgewiesen wurden. Es wird eine, in dieser Form erstmals angewandte, konsistente Untersuchung durchgeführt, bei der jede Radiogalaxie auf identische Weise, mittels zeitgleich aufgezeichneter Daten, analysiert wird. Dieser Ansatz unterscheidet diese Arbeit von vergleichbaren Studien. Die Fermi-LAT Rohdaten für jede Quelle werden für die Zeiträume analysiert, in denen diese direkt mit der Beobachtung hochenergetischer Gammastrahlung durch Cherenkov-Teleskope, sowie darüber hinaus mit weiteren Wellenlängenbereichen, überlappen. Das Synchrotron Self-Compton (SSC) Modell wird der Analyse zu Grunde gelegt und ermöglicht eine akkurate Beschreibung, der im AGN Jet auftretenden, Synchrotron Prozesse und inversen Compton-Streuung, sowie die Abschätzung physikalischer Charakteristiken der Quelle. Es stellt sich heraus, dass die Spektren von M87, NGC 1275, Pictor A und Centaurus A mit demselben SCC Modell gut beschrieben werden können und relativ konsistente Werte für physikalische Größen, wie zum Beispiel den Doppler-Faktor oder die Magnetfeldstärke liefern. Zur genaueren Charakterisierung der aus der Annihilation dunkler Materie resultierenden diffusen Emission, werden die SED der Radiogalaxien zusätzlich mit einem Modell für dunkle Materie gefittet. Die daraus resultierende, geschätzte Teilchenmasse für dunkle Materie liegt mit 4.7 TeV innerhalb des vorhergesagten Bereiches. Die hochdichten Regionen in der Nähe der schwarzen Löcher des AGN liefern ideale Voraussetzungen zur Detektion dieser Signaturen. Des Weiteren wurde herausgefunden, dass etwaige Unterschiede zwischen der erwarteten und der beobachteten Emission in den Spektren einiger Radiogalaxien mittels einer Kombination aus SSC Modell und dunkler Materie Modell erklärt werden können. Unter der Annahme, dass die der Annihilation dunkler Materie zu Grunde liegende Emission zeitlich konstant bleibt, stellen zum einen die Kombination des SSC- und dunkler Materie Modells, sowie die Erkenntnis, dass Charakteristiken dunkler Materie durch ähnliche Multi-Wellenlängen-Experimente während zukünftiger, emissionsarmer Zustände gefunden werden können, die wesentlichen Ergebnisse dieser Arbeit dar. Das Sample der Radiogalaxien wird anschließend erweitert, so dass es alle vom Fermi-LAT detektierte und Gammastrahlung emittierende Radiogalaxien umfasst. Im Anschluss daran wird eine Berechnung der aus dem Kernbereich stammenden, und der totalen Radioluminosität, sowie der Gammastrahlungs-Luminosität durchgeführt. Ein künftiger Schritt zur Erweiterung dieser Arbeit wäre die Abschätzung der Gammastrahlungs-Luminositätsfunktion von Radiogalaxien und deren prozentualer Beitrag zum totalen IGRB, basierend auf der weitläufig akzeptierten Annahme, dass eine vernünftige Abschätzung der Gammastrahlungs-Luminositätsfunktion einer Population mittels einer angemessenen Skalierung ihrer Radio-Luminositätsfunktion erreicht werden kann, da die Gammastrahlungs-Luminosität und die Radioluminosität stark miteinander korrelieren. Diese Arbeit hat die hierfür benötigten Grundlagen für diese Art von Berechnung gelegt, indem sie die Theorie und die ersten Schritte darlegt. Es ist die Hoffnung, dass der große Umfang der zusammengetragenen Daten, deren Simultanität, und die Anwendung einer konsistenten Analysemethode für das gesamte Sample eine verbesserte Grundlage für zukünftige Berechnungen des Beitrages dieser Population zum IGRB leistet, sowie strengere Anforderung für Multi-Wellenlängen-Experimente. Active Galactic Nuclei Dark Matter Gamma-Ray Astronomy Radio Galaxies ddc:530

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