Search for cosmic point sources of high energy neutrinos with the AMANDA-II detector

Hauschildt, Tonio

15 October 2004

Diese Arbeit befasst sich mit der Suche nach astrophysikalischen Punktquellen hochenergetischer Neutrinos mit Hilfe des AMANDA-II-Detektors. Der AMANDA-Detektor erlaubt die Rekonstruktion neutrino-induzierter Myonen durch die Detektion des von diesen Myonen emittierten Cherenkov-Lichts. Es wird der Datensatz des Jahres 2000 mit einer effektiven Datennahmezeit von 197 Tagen analysiert. Nach der Unterdrückung eines wesentlichen Teils des Untergrundes atmosphärischer Myonen durch Selektion als aufwärts laufend rekonstruierter Ereignisse werden weitere Selektionskriterien entwickelt, um einen Datensatz herauszufiltern, der von durch atmosphärische Neutrinos induzierten Myonen dominiert ist. Diese 699 Ereignisse werden im Hinblick auf signifikante Beiträge von Punktquellen untersucht, d.h. auf Überschüsse der Ereigniskonzentration aus bestimmten Richtungen. Weder die Betrachtung einer Auswahl möglicher Neutrinoquellen (z.B. aktive galaktische Kerne, Mikroquasare oder Supernova-Überreste), noch eine Suche am gesamten Nordhimmel durch die Platzierung überlappender Suchfenster, noch die Untersuchung der Raumwinkel-Abstände zwischen Paaren selektierter Ereignisse ergeben einen signifikanten Hinweis auf die Existenz von Quellen astrophysikalischer hochenergetischer Neutrinos. Unter der Annahme eines Neutrinospektrums dN/dE ~ E^(-2) werden Flussgrenzen für die Neutrino-Flüsse der ausgewählten Quellenkandidaten sowie für die neutrino-induzierten Myonflüsse angegeben, die im Mittel bei der Sensitivität von E^2 dN(Neutrinos)/dE = 2*10^(-7) GeV cm^(-2) s^(-1) bzw. N(Myonen) = 2*10^(-15) cm^(-2) s^(-1) liegen. Dies sind zur Zeit die besten Grenzen für die Neutrinoflüsse von astrophysikalischen Quellen in der nördlichen Hemisphäre. / We describe the search for astrophysical sources of high energy neutrinos with the AMANDA-II detector. This detector allows for reconstruction of neutrino induced muon tracks by the Cherenkov radiation emitted by relativistic muons. We analyze the AMANDA-II data recorded in the year 2000 with a lifetime of 197 days. A large fraction of the background of atmospheric muons can be suppressed by the selection of events reconstructed as upward moving tracks. We develop further quality criteria, which lead to the extraction of a sample of 699 neutrino event candidates, dominated by atmospheric neutrinos. We analyze this data sample in view of significant contributions from neutrino point sources, which would be observable as enhancements of the event density from certain directions. We have not found a significant indication of the existence of astrophysical high energy neutrino sources, neither by the investigation of source candidates (e.g. Active Galactic Nuclei, microquasars, or supernova remnants), nor by a binned search in the complete Northern sky, nor by the investigation of angular distances between pairs of reconstructed event directions. Assuming power-law neutrino spectra dN/dE ~ E^(-2), we calculate limits on the neutrino fluxes and the neutrino induced muons fluxes from a list of selected neutrino source candidates. The sensitivity of the AMANDA-II detector, i.e. the average neutrino and muon flux limits, amounts to E^2 dN(neutrinos)/dE = 2*10^(-7) GeV cm^(-2) s^(-1) and N(muons) = 2*10^(-15) cm^(-2) s^(-1), respectively. These are currently the best limits on neutrino fluxes from astrophysical objects in the Northern hemisphere.

AMANDA

Neutrinos

Astroteilchenphysik

Punktquellen

AMANDA

neutrinos

astroparticle physics

point sources

530 Physik

29 Physik, Astronomie

ddc:530

Characterizing cosmic neutrino sources

Mohrmann, Lars

30 November 2015

Das IceCube Neutrino Observatorium ist ein km^3-großes Neutrinoteleskop und befindet sich am geographischen Südpol. Das Ziel des Experiments ist es, kosmische Neutrinos nachzuweisen. Es wird erwartet, dass solche Neutrinos in Wechselwirkungen von hochenergetischer kosmischer Strahlung mit Materie oder Photonen in der Nähe ihrer Beschleunigungsumgebung entstehen. Der erste Nachweis für einen Fluss von kosmischen Neutrinos wurde von der IceCube-Kollaboration erbracht. Der Ursprung des Flusses ist noch nicht bekannt, dennoch können die Eigenschaften der Quellen durch eine Messung des Energiespektrums und der Zusammensetzung aus Elektron-, Muon-, und Tau-Neutrinos des Flusses eingeschränkt werden. Die vorliegende Arbeit stellt die erste umfassende Analyse von Daten des IceCube-Experiments im Hinblick auf diese Eigenschaften des Flusses dar. Hierfür wurden mehrere Datensätze kombiniert und gemeinsam analysiert. Es wurden experimentell beobachtete Verteilungen von rekonstruierter Energie, Zenithwinkel und Teilchen-Signatur mit Modellverteilungen angepasst. Unter der Annahme, dass der Fluss isotrop ist und zu gleichen Teilen aus allen Neutrino-Flavors besteht, wird das Spektrum durch ein Potenzgesetz mit Normalisierung (6.7_{-1.2}^{+1.1})x10^{-18}GeV^{-1}s^{-1}sr^{-1}cm^{-2} bei 100 TeV und spektralem Index -2.50+-0.09 zwischen Neutrino-Energien von 25 TeV und 2.8 PeV gut beschrieben. Ein spektraler Index von -2 kann mit einer Signifikanz von 3.8 Standardabweichungen ausgeschlossen werden. Die Flavor-Zusammensetzung ist kompatibel mit Erwartungen für Standard-Prozesse der Neutrino-Produktion. Die ausschließliche Produktion von Elektron-Neutrinos kann hingegen mit einer Signifikanz von 3.6 Standardabweichungen ausgeschlossen werden. Unter der Annahme, dass die Neutrino-Flavor während der Propagation von den Quellen zur Erde durch Standard-Neutrino-Oszillationen transformiert werden, beträgt der gemessene Anteil an Elektron-Neutrinos an der Erde (18+-11)%. / The IceCube Neutrino Observatory is a km^3-sized neutrino telescope located at the geographical South Pole. Its primary purpose is the detection of high-energy cosmic neutrinos. Such neutrinos are expected to be produced in interactions of high-energy cosmic rays with ambient matter or photons close to their acceleration sites. The IceCube Collaboration has reported the first evidence for a flux of high-energy cosmic neutrinos. While the origin of the flux remains unknown so far, the properties of its sources can be constrained by measuring its energy spectrum and its composition of electron, muon, and tau neutrinos. The present work constitutes the first comprehensive analysis of IceCube data with respect to these principal characteristics of the flux. Several data sets were assembled and simultaneously studied in a combined analysis. Experimentally observed distributions of reconstructed energy, zenith angle and particle signature were fitted with model distributions. Assuming the cosmic neutrino flux to be isotropic and to consist of equal flavors at Earth, the all-flavor spectrum is well described by a power law with normalization (6.7_{-1.2}^{+1.1})x10^{-18}GeV^{-1}s^{-1}sr^{-1}cm^{-2} at 100 TeV and spectral index -2.50+-0.09 for neutrino energies between 25 TeV and 2.8 PeV. A spectral index of -2 is disfavored with a significance of 3.8 standard deviations. The flavor composition is compatible with that expected for standard neutrino production processes at the sources. However, a scenario in which only electron neutrinos are produced is disfavored with a significance of 3.6 standard deviations. Assuming that standard neutrino oscillations transform the neutrino flavors during propagation from the sources to the Earth, the measured fraction of electron neutrinos at Earth is (18+-11)%.

Astroteilchenphysik

Spektrum

Neutrino

IceCube

Flavor

Spectrum

IceCube

Astroparticle physics

Neutrino

Flavor

530 Physik

29 Physik, Astronomie

ddc:530

Phenomenology of Inert Scalar and Supersymmetric Dark Matter

Lundström, Erik

January 2010

While the dark matter has so far only revealed itself through the gravitational influence it exerts on its surroundings, there are good reasons to believe it is made up by WIMPs – a hypothetical class of heavy elementary particles not encompassed by the Standard Model of particle physics. The Inert Doublet Model constitutes a simple extension of the Standard Model Higgs sector. The model provides a new set of scalar particles, denoted inert scalars because of their lack of direct coupling to matter, of which the lightest is a WIMP dark matter candidate. Another popular Standard Model extension is that of supersymmetry. In the most minimal scenario the particle content is roughly doubled, and the lightest of the new supersymmetric particles, which typically is a neutralino, is a WIMP dark matter candidate. In this thesis the phenomenology of inert scalar and supersymmetric dark matter is studied. Relic density calculations are performed, and experimental signatures in indirect detection experiments and accelerator searches are derived. The Inert Doublet Model shows promising prospects for indirect detection of dark matter annihilations into monochromatic photons. It is also constrained by the old LEP II accelerator data. Some phenomenological differences between the Minimal Supersymmetric Standard Model and a slight extension, the Beyond the Minimal Supersymmetric Standard Model, can be found. Also, supersymmetric dark matter models can be detected already within the early LHC accelerator data.

Dark matter

inert scalars

supersymmetry

indirect detection

accelerator searches

Physics

Fysik

Astroparticle physics

Astropartikelfysik

Elementary particle physics

Elementarpartikelfysik

Search for Gamma-ray Lines from Dark Matter with the Fermi Large Area Telescope

Ylinen, Tomi

January 2010

Dark matter (DM) constitutes one of the most intriguing but so far unresolved issues in physics. In many extensions of the Standard Model of particle physics, the existence of a stable Weakly Interacting Massive Particle (WIMP) is predicted. The WIMP is an excellent DM particle candidate. One of the most interesting scenarios is the creation of monochromatic gamma-rays from the annihilation or decay of these particles. This type of signal would represent a “smoking gun” for DM, since no other known astrophysical process should be able to produce it. In this thesis, the search for spectral lines with the Large Area Telescope (LAT) onboard the Fermi Gamma-ray Space Telescope (Fermi) is presented. The satellite was successfully launched from Cape Canaveral in Florida, USA, on 11 June, 2008. The energy resolution and performance of the detector are both key factors in the search and are investigated here using beam test data, taken at CERN in 2006 with a scaled-down version of the Fermi-LAT instrument. A variety of statistical methods, based on both hypothesis tests and confidence interval calculations, are then reviewed and tested in terms of their statistical power and coverage. A selection of the statistical methods are further developed into peak finding algorithms and applied to a simulated data set called obssim2, which corresponds to one year of observations with the Fermi-LAT instrument, and to almost one year of Fermi-LAT data in the energy range 20–300 GeV. The analysis on Fermi-LAT data yielded no detection of spectral lines, so limits are placed on the velocity-averaged cross-section, <img src="http://www.diva-portal.org/cgi-bin/mimetex.cgi?%3C%5Csigma%20v%3E_%7B%5Cgamma%20X%7D" />, and the decay lifetime, <img src="http://www.diva-portal.org/cgi-bin/mimetex.cgi?%5Ctau_%7B%5Cgamma%20X%7D" />, and theoretical implications are discussed. / QC20100525 / GLAST

Fermi

Large Area Telescope

gamma-rays

dark matter

spectral lines

beam test

Physics

Fysik

Astroparticle physics

Astropartikelfysik

The IceCube Neutrino Observatory: search for extended sources of neutrinos and preliminary study of a communication protocol for its future upgrade

Pinat, Elisa

27 June 2017

English Version: When humans started looking out at a starry night, astronomy was born. Photons emitted by stars travel up to sometimes billions of light years to reach our eyes, and by studying the properties of this photon flux we are able to infer properties of the star itself. Instead of photons, the IceCube Observatory, located at South Pole, aims at detecting neutrinos and hopes to shed some light on the still unsolved mystery of cosmic-ray acceleration and production mechanisms, and on the most energetic phenomena of the Universe. At the time of this writing, IceCube has proven the existence of an astrophysical neutrino flux with a significance exceeding seven sigmas. Nevertheless, the observed astrophysical neutrino flux shows no significant directional clustering nor a clear association with any known source class so far. Also the latest results given by IceCube’s point source analysis show no significant clustering as well. It is therefore important to widen the search to different source topologies to maximize the discovery potential. In the first part of this work we present an extended source analysis with seven years of IceCube data, adding three years of data to the previous published work and implementing a novel likelihood formulation. Since the extensions of any potential sources are not known a priori, five different extensions have been considered, from 1° to 5°. No significant clustering is observed in any of the maps. The ability of IceCube to establish neutrino astronomy by finding neutrino sources is limited by the number of cosmic neutrinos measured. Despite the aforementioned discovery of an astrophysical flux, detailed spectral studies and searches for specific source locations in this signal remain a challenge with the event sample sizes available from the IceCube instrument. Therefore, a considerable expansion of the current detector, IceCube Gen2, is promoted, which includes the instrumentation of a 10 km3 volume, able to deliver substantial increases in the astrophysical neutrino sample for all flavors. Not only the hardware will be upgraded, but many systems will undergo improvements, such as communications and timing infrastructures. A new communication system has been investigated and is presented in the second part of this document. Binary Phase Shift Keying (BPSK), the simplest digital modulation technique, has been studied as possible communication technique for IceCube Gen2. / French Version: Quand les humains ont commencé à regarder le ciel étoilé, l’astronomie est née. Les photons émis par les étoiles voyagent parfois des milliards d’années lumière avant d’atteindre nos yeux, et c’est grâce à l’étude de ce flux de photons que l’on peut déduire les propriétés des étoiles mêmes. Au lieu des photons, l’Observatoire IceCube, situé au Pôle Sud, a pour but de détecter des neutrinos :il espère éclairer le mystère encore non résolu de l’accéleration et des mécanismes de production des rayons cosmiques, ainsi que des phénomènes les plus énergétiques de l’Univers. Au moment où ce document a été rédigé, IceCube a démontré l’existence d’un flux de neutrinos astrophysiques avec une signification statistique excédant sept sigmas. Cependant, le flux de neutrinos astrophysiques observé ne montre aucun regroupement directionnel significatif ni une évidence d’association avec aucune source connue à l’heure actuelle. De plus, les derniers résultats fournis par les analyses de sources ponctuelles de la collaboration IceCube ne montrent non plus aucun regroupement. Il est donc important d’étendre ces recherches vers des typologies de sources différentes pour maximiser le potentiel de son découverte. Dans la première partie de ce travail nous présentons une analyse de source étendue basée sur sept années de données d’IceCube, ce qui rajoute trois ans de données au travail précédemment publié tout en mettant en oeuvre une nouvelle formulation de maximum de vraisem- blance. Comme les extensions de sources potentielles ne sont pas connues à priori, cinq extensions différentes ont été considérées, de 1° à 5°. Aucun regroupement significatif n’a été observé sur aucune des cartes. La capacité d’IceCube de consolider l’astronomie neutrino en découvrant des sources de neutrinos est limitée par le nombre de neutrinos cosmiques mesuré. Malgré la découverte susmentionnée d’un flux astrophysique, les études détaillées de spectre ainsi que les recherches de sources spécifiques pour ce type de signal demeurent un défi, à cause de la limitation de taille disponible des échantillons avec l’instrument IceCube. Par conséquent, une expansion considérable du détecteur actuel, IceCube Gen2, est promue :elle inclut l’instrumentation d’un volume de 10 km3, apte à fournir une augmentation importante des échantillons de neutrinos de toutes les saveurs. Non seulement le hardware sera mis à niveau, mais de nombreux autres systèmes subiront des améliorations, comme les infrastructures de communication et de timing. Un nouveau système de communication a été étudié et est présenté dans la deuxième partie de ce document. Le Binary Phase Shift Keying (BPSK), la technique de modulation numérique la plus simple, a été étudiée comme technique potentielle pour IceCube Gen2. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Astrophysique

Physique des particules élémentaires

Investigation of late flares in prompt GRB emission / Undersökning av sena pulser i ljuskurvor för GRB

Sandeberg, Johanna

January 2023

Gamma-ray bursts (GRBs) are the most energetic electromagnetic events in the universe, but there are still unanswered questions about them, like the underlying radiation mechanisms that cause the different parts of their light curves. Given that Wolf-Rayet (WR) stars with circumburst rings could be the progenitor of GRBs with late flares \cite{complex}, the purpose of this thesis was to determine if the precursor and the main emission of GRBs with late time flares might originate due to different radiation mechanisms, and thereby if WR stars could be the progenitors. 271 of the longest GRBs with flux above 10 photons/cm$^2$/s were studied and all GRBs with a precursor and a defined quiescent period were chosen for further studies. The chosen 39 GRBs were divided into different categories depending on the appearance of their light curves. A gold sample with $R_{P, max}/R_{D, max} &lt; 0.4$ and $T_Q/T_{tot} &gt; 0.5$, for the maximum count rate of the precursor $R_{P, max}$, the dominant emission $R_{D, max}$, and for the normalised quiescent period $T_Q/T_{tot}$ was concluded to have similar characteristics and to fit what would be expected if WR stars would be the progenitors. This group of GRBs all have a short and less bright precursor, a long quiescent period and a main emission which is brighter and longer than the precursor. The distributions of the photon index $\alpha$ for the precursor and the dominant emission for the gold sample indicate that the precursor is due to photospheric emission and the dominant emission is due to synchrotron emission. This is consistent with the interpretation that the precursor is a result of the jet interacting with the photosphere and the dominant emission is a result of interactions with the circumburst ring of a star like the WR stars. The next step in this investigation would be to study GRBs with more than one precursor that otherwise fit the description of the gold sample, to determine if these fit into the gold sample as well. / Gammablixtrar (GRB) är de mest kraftfulla elektromagnetiska eventen i universum men det finns fortfarande obesvarade frågor om dem, som de underliggande strålningsmekanismerna som orsakar de olika delarna av deras ljuskurvor. För en del av alla GRBs tar det upp till eller mer än 100 sekunder från utlösningstiden till det att en topp ses i ljuskurvan. För dessa finns då ofta en liten svag topp, som följs av en lång lugn period och sedan den dominant, starkare utstrålningen. GRBs tros kunna härstamma från Wolf-Rayet-stjärnor (WR-stjärnor), som är massiva, döende stjärnor som kan vara omringade av bubblor, nebulosor, och ringar. Om GRBs härstammar från dessa förväntas den första mindre toppen och den andra större toppen uppkomma på grund av olika strålningsprocesser. Syftet med detta projekt var därför att undersöka huruvida dessa toppar uppkommer på grund av olika processer eller ej. Sammanfattningsvis så hittades en distinkt och homogen grupp av GRBs med likande egenskaper. Resultaten påvisar att den första svaga toppen är fotosfärisk strålning, så att den uppkommer på grund av att jetstrålen från GRBn interagerar med fotosfären. Därtill tyder resultaten på att den dominanta starkare toppen är synkrotronstrålning, som kan uppkomma när jetstrålen interagerar med en ring runt en WR-stjärna. Nästa steg i detta projekt skulle vara att studera GRBs med fler än en mindre topp innan den dominant utstrålningen, för att se om dessa också har liknande egenskaper som de som hittades i den homogena gruppen.

astroparticle physics

gamma ray burst

photospheric emission

synchrotron emission

astropartikelfysik

gammablixt

fotosfärisk strålning

synkrotronstrålning

Physical Sciences

Fysik

Cosmic Ray Instrumentation and Simulations

McBride, Keith William

29 September 2021

No description available.

Astrophysics

Physics

cosmic-rays

ANITA

HELIX

GALPROP

astroparticle physics

clock isotopes

galactic halo

drift chamber

magnet spectrometer

Exploring the potentials of next-generation, wavelength-shifting, optical sensors for IceCube

Beise, Jakob

January 2023

The IceCube Neutrino Observatory has sensitivity to MeV electron antineutrinos from core-collapse supernovae through an excess of the detection rate over the background. Wavelength-shifting sensors have the potential to greatly increase photon collection making it a promising candidate for improving the measurement of the supernova neutrino light curve in IceCube-Gen2. For high-energy neutrino reconstruction, the competing effect of increased photon collection and the broader time distribution necessitate detailed simulations to determine the impact. In this thesis, we investigate the sensitivity gain caused by wavelength shifters in a future IceCube-Gen2 detector regarding the detection of faint modulations of the supernova neutrino lightcurve. Furthermore, we lay the groundwork for a future high-energy reconstruction through the implementation and integration of wavelength-shifting sensors into the IceCube simulation framework.

Neutrino Physics

Astroparticle Physics

Supernovae

Wavelength Shifters

IceCube

Astronomy, Astrophysics and Cosmology

Astronomi, astrofysik och kosmologi

Subatomic Physics

Subatomär fysik

A Search for Ultra-high Energy Cosmic Neutrinos: Data Analysis of the Antarctic Impulsive Transient Antenna, Third Flight

Stafford, Samuel J.

07 December 2017

No description available.

Physics

Astrophysics

neutrinos

interferometry

radio

antarctica

ANITA

antarctic impulsive transient antenna

ultra high energy neutrinos

astroparticle physics

askaryan

Interações hadrônicas a altíssimas energias e o desenvolvimento de cascatas atmosféricas extensas / Hadronic interactions and the development of extensive air showers

Soares, Hendrik Marques

28 November 2018

O comportamento das interações hadrônicas para energias de centro de massa superiores a 50 TeV/núcleon é uma fonte importante de incerteza sistemática na interpretação de dados de observatórios de raios cósmicos. Nesta tese, estudamos por meio de simulações de Monte Carlo observáveis dos chuveiros atmosféricos que pudessem ser correlacionados com aspectos dos diferentes modelos destas interações. Especial atenção foi dada à componente muônica que sabidamente é gerada do decaimento de partículas de natureza hadrônica na cascata. A precisão e a acurácia de uma rede esparsa de contadores de múons foram estudadas como função da granularidade da rede de detectores e da área de coleção de suas células. Mostramos, em particular, as diferenças na dependência radial da densidade de múons no plano transversal ao eixo da cascata para os diferentes modelos. Tais diferenças se mostram mais acentuadas na vizinhança do eixo e poderiam ser exploradas experimentalmente com um detector com alcance dinâmico suficiente para evitar saturação da eletrônica. Além disso, por meio de um tratamento fenomenológico, investigamos o impacto no desenvolvimento do chuveiro causado por variações na distribuição de pseudorapidez $dN/d\\eta$ de secundários produzidos na colisão primária. Mostramos que diferentemente de quantidades como seção de choque inelástica, multiplicidade, razão de carga e elasticidade, mudanças em $dN/d\\eta$ que preservem tais quantidades são rapidamente diluídas nas sucessivas camadas de interações posteriores à colisão primária. / The behavior of the hadronic interactions at center of mass energies greater than 50 TeV/nucleon is an important source of systematic uncertainty on interpreting data from cosmic ray observatories. In this thesis, we study through Monte Carlo simulations the atmospheric shower observables that could be correlated with different aspects of these interactions. Special attention was paid to the muonic component that is known to be generated from the decay of hadronic particles. The precision and accuracy of a sparse grid of muon counters were studied as a function of the array granularity and the collection area of its cells. In particular, we studied the differences in the radial dependence of the muon density in the shower plane for different models. These differences are shown to be larger in the vicinity of the shower axis and, therefore, could be explored with a detector of sufficiently large dynamic range as to avoid saturation of its acquisition electronics. In addition, through a phenomenological treatment, we investigated the impact on the shower development caused by variations in the distribution of pseudorapidity $ dN/d\\eta $ of secondaries particles produced in the primary collision. We show that unlike quantities such as inelastic cross section, multiplicity, charge ratio and elasticity, changes in $ dN/d\\eta $ that preserve such quantities are rapidly diluted in successive interaction layers subsequent to the primary collision.

Astroparticle physics

Astropartículas

Chuveiros atmosféricos extensos

Cosmic rays

Extensive air shower

Hadronic interaction

Interações hadrônicas

Observatório Pierre Auger

Pierre Auger Observatory

Raios cósmicos