Global ETD Search

21	Search for neutrino-induced cascades with 5 years of the AMANDA-II data Actis, Oxana 12 November 2008 (has links) Das Antarctic Muon And Neutrino Detector Array (AMANDA) ist ein Cherenkov Detektor, der sich im Gletscher der Antarktis am Südpol befindet. Wir präsentieren die Analyse von Daten, die in den Jahren 2000 bis 2004 gesammelt wurden, die einer effektiven Detektorlaufzeit von 1001 Tagen entsprechen. Die Suche zielt auf den Nachweis von elektomagnetische und hadronische Teilchenschauern, so gennante Kaskaden, die durch Elektron- und Tauneutrinowechselwirkung produziert werden können. Die hadronischen Kaskaden können auch über neutrale Ströme Wechselwirkung von Neutrinos aller Arten produziert werden. Der Kaskadenkanal hat einige Vorteile in der Suche nach einem diffusen Fluss von astrophysikalischen Neutrinos. Durch die gute Energieauflösung des AMANDA Detektors kann man zwischen einem harten astrophysikalische Spektrum und einem weichen atmosphärischen Spektrum unterscheiden. Außerdem ist der atmosphärischen Elektronneutrinos Fluss um eine Gößenordnung kleiner als der atmosphärische Myonneutrinofluss. Der Untergrund von atmosphärischem Myonen aus Luftschauern kann unterdrückt werden, weil diese als Spuren im Detektor erscheinen und leicht zu identifizieren sind. Mit der hohen Untergrundunterdrückung ist es möglich die Analyse über einen Raumwinkel von 4pi für Energien gegen 50 TeV zu erstrecken. Die Anzahl von gefundenen Ereignissen in dieser Analyse stimmt mit der Erwartung von Hintergrundereignissen überein. Deshalb berechnen wir eine obere Grenze für den diffusen Neutrinofluss aller Neutrinoarten, unter der Annahme, dass alle Neutrinoarten im Verhältnis 1:1:1 auftreten. Die obere Grenze für einen Nuetrinofluss im Energiebereich von 40 TeV bis 9 PeV mit einem Spektrum von E-2 ist 3.96x10-7 GeV s-1 sr-1 cm-2 bei einem Konfidenzniveau von 90%. Dies ist momentan die niedrigste Grenze für einen diffusen Neutrinoflüss aller Neutrinoarten. / The Antarctic Muon And Neutrino Detector Array (AMANDA) is a Cherenkov detector deployed in the Antarctic ice cap at the South Pole. We present the analysis of the AMANDA data collected during 1001 effective days of the detector lifetime be tween the years 2000 and 2004. We focus our search on electromagnetic and hadronic cascades which are produced in charged-current interactions of high-energy electron or tau neutrinos and in neutral-current interactions of neutrinos of any flavor. There are several advantages associated with the cascade channel in the search for a "diffuse" flux of astrophysical neutrinos. The AMANDA''s energy resolution allows us to distinguish between a hard astrophysical spectrum and a soft atmospheric spectrum. In addition, the flux of atmospheric electron neutrinos is lower than that of atmospheric muon neutrinos by one order of magnitude, and the background from downward-going atmospheric muons can be suppressed due to their track-like topology. The low background in this channel allows us to attain a 4pi acceptance above energies of about 50 TeV. The number of events observed in this analysis is consistent with the background expectations. Therefore, we calculate an upper limit on the diffuse all-flavor neutrino flux assuming a flavor ratio 1:1:1 at the detection site. A flux of neutrinos with a spectrum falling as E-2 is limited to 3.96x10-7 GeV s-1 sr-1 cm-2 at 90% C.L. for a neutrino energy range spanning from 40 TeV to 9 PeV. This upper limit is currently the most sensitive limit on the diffuse all-flavor astrophysical neutrino flux. AMANDA Neutrino Astroteilchenphysik Kaskaden AMANDA neutrinos astroparticle physics cascades 530 Physik 29 Physik, Astronomie ddc:530
22	Antiparticle identification studies for the PAMELA satellite experiment Lund, Jens January 2004 (has links) The PAMELA satellite experiment will soon be launched and during its 3 year mission perform measurement of charged particle fluxes in the cosmic radiation. PAMELA is specifically designed to identify antiprotons and positrons in the vast background of other charged particles. These antiparticle measurements will be performed using: a permanent magnet spectrometer, a scintillator based time of flight system, an electromagnetic imaging calorimeter, a transition radiation detector and a scintillator triggered neutron detector. There is also a scintillator based anticoincidence system to reject spurious triggers from out of acceptance events (developed and built at KTH). These detectors will allow the background in the antiproton and positron measurements to be significantly reduced, and PAMELA will thus be able to perform high precision measurements with unprecedented statistics and over a wide energy range, far surpassing any previous experiment. To determine the antiparticle identification and background rejection capability of the experiment, studies have been performed using simulations and data collected at particle beams. These studies have focused on: the proton rejection in positron measurements (using the calorimeter), contamination by locally produced pions in antiproton measurements and estimations of the expected statistics due to the energy dependence (caused by e.g. the geomagnetic field and the magnetic field in the spectrometer) of the gathering power. This work significantly extends previous studies of the PAMELA performance in antiparticle identification. Space technology PAMEL satellites astroparticle physics antiparticles calorimeters Rymdteknik Space engineering Rymdteknik
23	Antiparticle identification studies for the PAMELA satellite experiment Lund, Jens January 2004 (has links) <p>The PAMELA satellite experiment will soon be launched and during its 3 year mission perform measurement of charged particle fluxes in the cosmic radiation. PAMELA is specifically designed to identify antiprotons and positrons in the vast background of other charged particles. These antiparticle measurements will be performed using: a permanent magnet spectrometer, a scintillator based time of flight system, an electromagnetic imaging calorimeter, a transition radiation detector and a scintillator triggered neutron detector. There is also a scintillator based anticoincidence system to reject spurious triggers from out of acceptance events (developed and built at KTH). These detectors will allow the background in the antiproton and positron measurements to be significantly reduced, and PAMELA will thus be able to perform high precision measurements with unprecedented statistics and over a wide energy range, far surpassing any previous experiment. To determine the antiparticle identification and background rejection capability of the experiment, studies have been performed using simulations and data collected at particle beams. These studies have focused on: the proton rejection in positron measurements (using the calorimeter), contamination by locally produced pions in antiproton measurements and estimations of the expected statistics due to the energy dependence (caused by e.g. the geomagnetic field and the magnetic field in the spectrometer) of the gathering power. This work significantly extends previous studies of the PAMELA performance in antiparticle identification.</p> Space technology PAMEL satellites astroparticle physics antiparticles calorimeters Rymdteknik Space engineering Rymdteknik
24	Search for high energy GRB neutrinos in IceCube Casey, James David 21 September 2015 (has links) The IceCube Neutrino Observatory has reported the observation of 35 neutrino events above 30 TeV with evidence for an astrophysical neutrino flux using data collected from May 2010 to May 2013. These events provide the first high-energy astrophysical neutrino flux ever observed. The sources of these events are currently unknown. IceCube has looked for correlations between these events and a list of TeV photon sources including a catalog of 36 galactic sources and 42 extragalactic sources, correlations with the galactic plane and center, and spatial and temporal clustering. These searches have shown no significant correlations. The isotropic distribution of the event directions gives indications that the events could be extragalactic in nature and therefore may originate in the same processes that generate ultra-high-energy cosmic rays (UHECRs). The sources of these UHECRs are still unknown; however, gamma-ray bursts (GRBs) have been proposed as one possible source class. By determining the source of these high-energy neutrinos, it may be possible to determine the sources of UHECRs as well. This study is a search for directional and temporal correlation between 856 GRBs and the astrophysical neutrino flux observed by IceCube. Nearly 10,000 expanding time windows centered on the earliest reported time of the burst were examined. The time windows start at ±10 s and extend to ±15 days. We find no evidence of correlations for these time windows and set an upper limit on the fraction of the astrophysical flux that can be attributed to the observed GRBs as a function of the time window. GRBs can contribute at most 12% of the astrophysical neutrino flux if the neutrino-GRB correlation time is less than ≈20 hours, and no more than 38% of the astrophysical neutrino flux can be attributed to the known GRBs at time scales up to 15 days. We conclude that GRBs observable by satellites are not solely responsible for IceCube’s astrophysical neutrino flux, even if very long correlation time scales are assumed. IceCube Neutrinos GRBs Gamma-ray bursts Astrophysics Particle astrophysics Astroparticle physics
25	Simulation of birefringence effects for high-energy neutrino detectors Heyer, Nils January 2021 (has links) The detection of high-energy neutrinos in the E > O(PeV) range requires newdetection techniques in order to cope with the decreasing flux. The radio detectionmethod uses Askaryan emission to detect these neutrinos. The propagation of theradio pulses has to be modeled carefully in order to estimate the properties of theneutrinos from the detected radio pulse. This report introduces a model whichwas implemented to the NuRadioMC code to simulate birefringence effects in theice of the South Pole. To do that, a new ice model was created which combinesthe density and directional dependence on the refractive index. With this icemodel and an analytical ray tracer the time delay and polarization resulting frombirefringence was simulated for different geometries. A directional dependenceon the magnitude of the time delay and the change of the polarization along thepropagation path was found. To model the mixing of the polarization states dueto this change in polarization a pulse propagation model was introduced. Timedelay calculations resulting from this model were compared to simulations andmeasurements from the ARA experiment and have shown good agreement. astroparticle physics radio detection high-energy neutrinos birefringence Subatomic Physics Subatomär fysik
26	Few-electron signals and their implications in liquid xenon time projection chambers Amanda Leigh Depoian (14210249) 07 December 2022 (has links) <p>The energy threshold of liquid xenon detectors is driven by the requirements of observing a scintillation signal as well as a large ionization signal. Observing both allows powerful background rejection, but limits the sensitivity below O(10 GeV/c<sup>2</sup>). Removing the requirement of having a scintillation signal, the threshold for light dark matter can be pushed lower. One limitation to the light dark matter search in XENON1T was single- and few-electron backgrounds that were not well understood. A dedicated analysis was performed to understand these backgrounds and event selections were developed to mitigate them. This thesis presents details of the characterization and results from a search for light dark matter using only the single- and few-electron ionization signals in the XENON1T detector.</p> <p><br></p> <p>These liquid xenon detectors are leading in sensitivity to search for rare events. With various detector upgrades, XENONnT has improved sensitivity to low-energy interactions with signals as low as a single detected electron. This allows XENONnT to be able to detect neutrinos of all flavors from potential Galactic supernovae via coherent elastic neutrino-nucleus scattering (CEvNS). This thesis presents an overview of the capability of XENONnT to detect supernova neutrinos via CEvNS. This allows XENONnT to be the first direct detection dark matter experiment to directly participate in the SuperNova Early Warning System.</p> Particle physics dark matter delayed electrons particle physics astrophysics
27	Very-high-energy gamma-ray observations of blazars with the MAGIC telescopes and performance study of the next-generation atmospheric Cherenkov telescope CTA-LST / MAGIC望遠鏡によるブレーザーからの超高エネルギーガンマ線観測および次世代大気チェレンコフ望遠鏡CTA-LSTの性能評価 Nozaki, Seiya 23 March 2022 (has links) 京都大学 / 新制・課程博士 / 博士(理学) / 甲第23702号 / 理博第4792号 / 新制\|\|理\|\|1686(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)准教授窪秀利, 教授鶴剛, 教授中家剛 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM Astroparticle Physics Very-High-Energy Gamma Ray Active Galactic Nuclei Blazar Imaging Atmospheric Cherenkov Telescope 400
28	Searches for Particle Dark Matter : Dark stars, dark galaxies, dark halos and global supersymmetric fits Scott, Pat January 2010 (has links) The identity of dark matter is one of the key outstanding problems in both particle and astrophysics. In this thesis, I describe a number of complementary searches for particle dark matter. I discuss how the impact of dark matter on stars can constrain its interaction with nuclei, focussing on main sequence stars close to the Galactic Centre, and on the first stars as seen through the upcoming James Webb Space Telescope. The mass and annihilation cross-section of dark matter particles can be probed with searches for gamma rays produced in astronomical targets. Dwarf galaxies and ultracompact, primordially-produced dark matter minihalos turn out to be especially promising in this respect. I illustrate how the results of these searches can be combined with constraints from accelerators and cosmology to produce a single global fit to all available data. Global fits in supersymmetry turn out to be quite technically demanding, even with the simplest predictive models and the addition of complementary data from a bevy of astronomical and terrestrial experiments; I show how genetic algorithms can help in overcoming these challenges. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 5: Accepted. Paper 6: Submitted. dark matter supersymmetry gamma rays dwarf galaxies stellar evolution cosmological perturbations phase transitions statistical techniques Astroparticle physics Astropartikelfysik Astroparticle physics Astropartikelfysik Cosmology Kosmologi Elementary particle physics Elementarpartikelfysik Computational physics Beräkningsfysik Formation and development of stars Stjärnors bildning och utveckling High energy astrophysics Högenergiastrofysik
29	Supersymmetry vis-à-vis Observation : Dark Matter Constraints, Global Fits and Statistical Issues Akrami, Yashar January 2011 (has links) Weak-scale supersymmetry is one of the most favoured theories beyond the Standard Model of particle physics that elegantly solves various theoretical and observational problems in both particle physics and cosmology. In this thesis, I describe the theoretical foundations of supersymmetry, issues that it can address and concrete supersymmetric models that are widely used in phenomenological studies. I discuss how the predictions of supersymmetric models may be compared with observational data from both colliders and cosmology. I show why constraints on supersymmetric parameters by direct and indirect searches of particle dark matter are of particular interest in this respect. Gamma-ray observations of astrophysical sources, in particular dwarf spheroidal galaxies, by the Fermi satellite, and recording nuclear recoil events and energies by future ton-scale direct detection experiments are shown to provide powerful tools in searches for supersymmetric dark matter and estimating supersymmetric parameters. I discuss some major statistical issues in supersymmetric global fits to experimental data. In particular, I further demonstrate that existing advanced scanning techniques may fail in correctly mapping the statistical properties of the parameter spaces even for the simplest supersymmetric models. Complementary scanning methods based on Genetic Algorithms are proposed. / At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Submitted. supersymmetry dark matter gamma rays dwarf galaxies direct detection statistical techniques scanning algorithms genetic algorithms statistical coverage Astroparticle physics Astropartikelfysik Cosmology Kosmologi Astroparticle physics Astropartikelfysik
30	Studium urychlování vysokoenergetických částic v extragalaktických objektech / Studium urychlování vysokoenergetických částic v extragalaktických objektech Štefánik, Stanislav January 2013 (has links) Title: Study of Cosmic-Ray Acceleration in Extragalactic Objects Author: Stanislav tefnik Department: Institute of Particle and Nuclear Physics Supervisor: RNDr. Dalibor Nosek, Dr. Abstract: This thesis deals with production processes of cosmic γ-rays in astro- physical objects and methods of their detection. Possible interactions leading to the emission of high energy γ-rays in the active galaxy Centaurus A are discussed in this context. Cherenkov Telescope Array is presented as a new experiment fo- cused on the detection of air showers initiated by cosmic γ-rays. Cherenkov light of air showers is studied in the simulations done by CORSIKA simulation tool. Method of data analysis within the framework of Cherenkov telescopes is descri- bed and performed on the dataset of the active galaxy PKS 2155-304. The results include statistical tests of γ-ray source presence and its time variability. Keywords: Cosmic rays, gamma rays, astroparticle physics, high energy astro- physics, acceleration, CTA experiment

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