Global ETD Search

191	Étude des antineutrinos de réacteurs : mesure de l'angle de mélange leptonique θ₁₃ et recherche d'éventuels neutrinos stériles / Reactor Anti-neutrinos : measurement of the θ₁₃ leptonic mixing angle and search for potential sterile neutrinos Collin, Antoine 07 January 2014 (has links) L’expérience Double Chooz a pour but la mesure précise de l’angle de mélange θ₁₃. Son évaluation repose sur l’étude de la disparition des antineutrinos produits par les réacteurs de la centrale de Chooz, disparition due au phénomène d’oscillation des neutrinos. Deux détecteurs identiques composés de liquide scintillant permettent d’effectuer une mesure relative, diminuant ainsi les incertitudes systématiques. Le détecteur proche, qui fournit la normalisation du flux de neutrinos émis, est en cours d’installation, son achèvement est prévu pour le printemps 2014. Le détecteur lointain, sensible à l’effet de θ₁₃, est situé à un kilomètre environ et prend des données depuis 2011. Dans cette première phase de l’expérience, les données acquises par le détecteur lointain sont comparées à une prédiction du flux de neutrinos émis par les réacteurs pour estimer le paramètre θ₁₃. Au sein de cette thèse, l’expérience Double Chooz et son analyse sont présentées. Une attention particulière est portée à l’étude des bruits de fond et au rejet de signaux parasites constitués de flashs lumineux émis par les photo-multiplicateurs. Les flux de neutrons aux interfaces entre les différents volumes du détecteur affectent la définition du volume d’interaction et partant l’efficacité de détection. L’étude détaillée de ces effets de bord est présentée. Dans le cadre de l’expérience Double Chooz, des études ont été menées afin d’améliorer la prédiction des flux de neutrinos émis par les réacteurs. Ces travaux ont mis à jour un déficit des taux de neutrinos observés dans les expériences passées à courtes distances des réacteurs. Ce déficit pourrait s’expliquer par une oscillation vers une saveur stérile. Le projet Stereo a pour but d’observer la distorsion — caractéristique de l’oscillation — du spectre des neutrinos en énergie et en distance de propagation. Cette thèse s’attache à présenter le concept du détecteur, les simulations réalisées, ainsi que les études de sensibilité. Les différents bruits de fond et les blindages envisagés pour s’en prémunir sont enfin discutés. / The Double Chooz experiment aims to measure the θ₁₃ mixing angle through the disappearance—induced by the oscillation phenomenon—of anti-neutrinos produced by the Chooz nuclear reactors. In order to reduce systematic uncertainties, the experiment relies on the relative comparison of detected signals in two identical liquid scintillator detectors. The near one, giving the normalization of the emitted flux, is currently being built and will be delivered in spring 2014. The far detector, sensitive to θ₁₃, is located at about one kilometer and is taking data since 2011. In this first phase of the experiment, the far detector data are compared to a prediction of the emitted neutrino flux to estimate θ₁₃. In this thesis, the Double Chooz experiment and its analysis are presented, especially the background studies and the rejection of parasitic signals due to light emitted by photo-multipliers. Neutron fluxes between the different detector volumes impact the definition of the fiducial volume of neutrino interactions and the efficiency of detection. Detailed studies of these effects are presented. As part of the Double Chooz experiment, studies were performed to improve the prediction of neutrino flux emitted by reactors. This work revealed a deficit of observed neutrino rates in the short baseline experiments of last decades. This deficit could be explained by an oscillation to a sterile state. The Stereo project aims to observe a typical signature of oscillations: the distortion of neutrino spectra both in energy and baseline. This thesis presents the detector concept and simulations as well as sensitivity studies. Background sources and the foreseen shielding are also discussed. Double Chooz Angle de mélange θ₁₃ Oscillations de neutrinos Stereo Neutrino stérile Liquide scintillant Double Chooz Θ₁₃ mixing angle Neutrino oscillations Stereo Sterile neutrino Liquide scintillator
192	Beta-decay emitted electronic antineutrinos as a tool for unsolved problems in neutrino oscillation physics / Antineutrinos électroniques émis par désintégration bêta comme outil pour problèmes non résolus en physique d'oscillation des neutrinos Fischer, Vincent 23 September 2015 (has links) Le cadre global des oscillations de neutrinos est maintenant bien compris et nous quittons une ère d'exploration pour une ère de précision. L'expérience Double Chooz a pour but de mesurer l'angle de mélange theta13 par l'étude des oscillations des antineutrinos électroniques produits par les réacteurs de la centrale nucléaire de Chooz. Dans cette thèse, une sélection préliminaire des neutrinos détectés dans le détecteur proche est présentée. Les résultats les plus récents de Double Chooz, desquels sont extraits la mesure de theta13 la plus précise que l'expérience peut fournir à ce jour, seront également discutés. La géométrie de l'expérience, relativement simple, représente un avantage considérable afin d'effecteur des études de directionalité des neutrinos dont les résultats, obtenus en analysant les jeux de données les plus récents avec captures sur Gd et H, sont présentés. Ce concept de directionalité peut être appliqué à l'astronomie/astrophysique en offrant la possibilité de localiser des supernovas après détection de leurs neutrinos. Les résultats de simulations de directionalité effectuées avec différentes combinaisons de détecteurs seront présentées. Enfin, plusieurs anomalies pourraient s'expliquer par l'existence de nouveaux états, stériles, de neutrinos. Le but de l¿expérience CeSOX est de confirmer ou réfuter cette hypothèse en déployant une source radioactive à coté d'un grand détecteur comme KamLAND ou Borexino. Dans cette thèse seront présentés les résultats des simulations de signaux et de bruits de fond effectuées afin de valider le principe de l'expérience et de s'assurer de sa sensibilité à l'observation d'une oscillation vers un neutrino stérile. / The framework of neutrino oscillations is quite well-understood and now requires precision rather than exploration. The Double Chooz experiment aims at measuring the theta13 mixing angle through the oscillations of electronic antineutrinos produced by the reactors of the Chooz nuclear power plant. The comparison of the interaction rates and spectral shapes in the two Double Chooz's detectors allows the observation of a disappearance and a spectral distortion, both driven by theta13. In this thesis, a preliminary neutrino selection with the near detector, whose data taking started in December 2014, has been performed. The most recent results of Double Chooz, providing the most precise measurement of the experiment, are presented as well.The simple layout of Double Chooz is a strong advantage to conduct directionality studies. Results of these studies using the most recent neutrino candidates with neutron captures on Gd and H are showed. Neutrino directionality can be applied to astronomy, with the localization of core-collapse supernovae. To this purpose, results of directionality measurements performed with combinations of large neutrino detectors over the globe are presented.Finally, recent anomalies observed in short baseline experiments provided hints of the hypothetical existence of additional sterile neutrino states. The goal of the CeLAND/CeSOX experiment is to test this hypothesis by deploying a radioactive source next to a large liquid scintillator detector such as KamLAND or Borexino. In this thesis, are presented results of signal and background simulations performed to validate the design and assess the sensitivity of such an experiment. Directionalité des neutrinos Désintégration beta inverse Supernova avec effondrement de coeur Neutrino stérile Oscillations de neutrinos Angle de mélange theta13 Neutrino oscillations Neutrino directionality 530
193	Matter asymmetry and gauge unification Cosme, Nicolas 28 September 2004 (has links) Pourquoi reste-t-il de la matière dans l’univers ? Depuis la découverte de l’anti-matière, miroir de la matière dont nous sommes constitués et s’annihilant de prime abord parfaitement avec cette dernière, ce mystère stimule l’étude des propriétés communes et distinctes entre particules et anti-particules. Dans ce cadre, il a été établi au vu des interactions dites de jauge (en particulier les interactions électrofaibles) que la symétrie intrinsèque entre particules et anti-particules est la combinaison subtile du conjugué de charge (C) et de la parité d’espace (P) : la symétrie CP. Ainsi, un comportement distinct entre matière et anti-matière est caractérisé au niveau fondamental par une violation de CP. D’une part, une telle violation a été mise en évidence expérimentalement dans la désintégration de mesons K et B, où la production de particules dans certains canaux est favorisée. D’autre part, la violation de CP est l’une des conditions requises à la création d’un excès de matière durant l’évolution de l’univers. Dans la présente thèse, nous étudions deux aspects de cette asymétrie entre matière et anti-matière. Tout d’abord, un scénario de création d’un excès de matière dans l’évolution de l’univers basé sur la désintégration de neutrinos lourds est étudié. Les récents résultats expérimentaux sur l’existence d’une masse pour les neutrinos rendent très attractif ce scénario. Bien que le schéma général repose uniquement sur les interactions liées à la masse des particules (secteur scalaire), nous le prolongeons ici dans la perspective plus naturelle de l’unification des interactions de jauge, seule motivation complète à l’inclusion de neutrinos lourds dans le spectre des particules. L’inclusion d’interactions de jauge liées aux neutrinos lourds complète ainsi la description. Les résultats tirés sur les paramètres de masse des neutrinos, grandes inconnues de la physique des particules, s’en voient modifiés de manière importante. Ensuite, la question de l’origine de la violation de CP est posée. En effet, dans la description standard des interactions faibles, la violation de CP est explicite et résulte uniquement de la liberté pour les couplages de masse (couplages de Yukawa) d’être des nombres complexes. Ainsi, aucune compréhension fondamentale sur la différence de comportement entre particules et anti-particules n’est apportée. Nous proposons dans ce sens une source de violation de CP par la compactification d’une théorie de jauge dans un espace de dimensions étendues. A partir de couplages réels, une valeur classique de la composante supplémentaire des bosons de jauge fournit une masse effective complexe aux fermions. Les conditions de l’obtention d’une violation de CP physique sont alors étudiées. Nous identifions la structure minimale pour rendre compte des interactions électrofaibles tout en incluant une source de violation de CP dans ce contexte. L’unification avec les interactions fortes est alors établie dans une structure qui apporte une lumière différente sur les schémas d’unification usuels. leptogenèse asymétrie de matière unification de jauge dimensions supplémentaires violation CP neutrino
194	A search for gamma ray burst neutrinos using the Radio Ice Cherenkov Experiment Harris, Pauline Lisa January 2008 (has links) The Radio Ice Cherenkov Experiment(RICE) located at the South Pole, is designed to detect the coherent broad-band radio Cherenkov radiation emitted when a high energy (10¹⁵ to 10¹⁸ eV) neutrino interacts with a nucleon in the ice. Observations have identified that Gamma Ray Bursts(GRBs) are possible sites for high energy neutrino production. We consider here GRBs which occurred in the years 2001 to 2005 inclusive during the operational times of RICE. Using GRB photon spectral data, we calculate the neutrino spectra predicted for these GRBs and the subsequent event number expected in RICE. We re-analyze RICE data in small time windows surrounding the GRB burst start times using a refined method involving by eye analysis of this reduced data set and find no neutrino events in the data set. Using the effective volume of RICE appropriate for each GRB we calculate neutrino flux limits for the GRBs. Although the flux limits are several orders of magnitude weaker than the expected flux, the RICE GRB neutrino limits are the only limits in the PeV to EeV energy range. Gamma Ray Burst Neutrino Radio Ice Cherenkov Experiment GRB RICE
195	Simulation of the Sudbury Neutrino Observatory neutral current detectors Wan Chan Tseung, Hok Seum January 2008 (has links) The Sudbury Neutrino Observatory (SNO), a heavy water Cherenkov experiment, was designed to detect solar Boron-8 neutrinos via their elastic scattering interactions on electrons, or charged current and neutral current (NC) interactions on deuterium. In the third phase of SNO, an array of Helium-3 proportional counters was deployed to detect neutrons produced in NC interactions. A simulation of the current pulses and energy spectra of the main kinds of ionization events inside these Neutral Current Detectors (NCDs) was developed. To achieve this, electron drift times in NCDs were evaluated with a Monte Carlo method, and constrained by using wire alpha activity inside the counters. The pulse calculation algorithm applies to any ionization event, and takes into account processes such as straggling, electron diffusion, and propagation through the NCD hardware. A space charge model was developed to fully explain the energy spectra of neutron and alpha events. Comparisons with data allowed the various classes of alpha backgrounds to be identified, and gave evidence for the spatial non-uniformity of Uranium-238 and Thorium-232 chain nuclei in the counter walls. The simulation was applied to determine the fractional contents of the main types of alpha backgrounds in each NCD string. The number of neutron capture events in the array was extracted via a statistical separation, using Monte Carlo generated alpha background pulse shape parameter distributions and minimal energy information. The inferred total Boron-8 solar neutrino flux is: φ<sub>NC</sub>< = 5.74 ± 0.77 (stat) ± 0.39 (sys) x 10<sup>6</sup> cm<sup>-2</sup>s<sup>-1</sup> in agreement with Standard Solar predictions and previous SNO results. 539.7
196	A search for solar dark matter with the IceCube neutrino detector : Advances in data treatment and analysis technique Zoll, Marcel Christian Robert January 2016 (has links) There is compelling observational evidence for the existence of dark matter in the Universe, including our own Galaxy, which could possibly consist of weakly interacting massive particles (WIMPs) not contained in the standard model (SM) of particle physics. WIMPs may get gravitationally trapped inside heavy celestial bodies of ordinary matter. The Sun is a nearby candidate for such a capture process which is driven by the scattering of WIMPs on its nuclei. Forming an over-density at the Sun's core the WIMPs would self-annihilate yielding energetic neutrinos, which leave the Sun and can be detected in experiments on Earth. The cubic-kilometer sized IceCube neutrino observatory, constructed in the clear glacial ice at the Amundsen-Scott South Pole Station in Antarctica offers an excellent opportunity to search for this striking signal. This thesis is dedicated to the search for these solar dark matter signatures in muon neutrinos from the direction of the Sun. Newly developed techniques based on hit clustering and hit-based vetos allow more accurate reconstruction and identification of events in the detector and thereby a stronger rejection of background. These techniques are also applicable to other IceCube analyses and event filters. In addition, new approaches to the analysis without seasonal cuts lead to improvements in sensitivity especially in the low-energy regime (<=100 GeV), the target of the more densely instrumented DeepCore sub-array. This first analysis of 369 days of data recorded with the completed detector array of 86 strings revealed no significant excess above the expected background of atmospheric neutrinos. This allows us to set strong limits on the annihilation rate of WIMPs in the Sun for the models probed in this analysis. The IceCube limits for the spin-independent WIMP-proton scattering cross-section are the most stringent ones for WIMP masses above 100 GeV. / IceCube neutrino WIMP dark matter cluster analysis sun IceCube IC86
197	Zdroj monoenergetických elektronů pro monitorování spektrometru v neutrinovém experimentu KATRIN / Zdroj monoenergetických elektronů pro monitorování spektrometru v neutrinovém experimentu KATRIN Slezák, Martin January 2011 (has links) The international project KATRIN (KArlsruhe TRItium Neutrino experiment) is a next- generation tritium beta decay experiment. It is designed to measure the electron antineutrino mass by means of a unique electron spectrometer with sensitivity of 0.2 eV/c2 . This is an improvement of one order of magnitude over the last results. Important part of the measurement will rest in continuous precise monitoring of high voltage of the KATRIN main spectrometer. The monitoring will be done by means of conversion electrons emitted from a solid source based on 83 Rb decay. Properties of several of these sources are studied in this thesis by means of the semiconductor gamma-ray spectroscopy. Firstly, measurement of precise energy of the 9.4 keV nuclear transition observed in 83 Rb decay, from which the energy of conversion electrons is derived, is reported. Secondly, measurement of activity distribution of the solid sources by means of the Timepix detector is described. Finally, a report on measurement of retention of 83 Rb decay product, the isomeric state 83m Kr, in the solid sources is given.
198	A time-dependent search for neutrino emission from microquasars with the ANTARES telescope Galata, Salvatore 05 April 2012 (has links) La Collaboration ANTARES exploite actuellement un détecteur sous-marin Che-renkov dédié à l'astronomie neutrino de haute énergie. Le but principal de cette expérience est de détecter les sources cosmiques de neutrinos, afin de révéler les sites de production des rayons cosmiques. Parmi les sources candidates figurent celles où a lieu l'accélération de ces rayons cosmiques dans les jets relativistes, comme les noyaux actifs de galaxie, les sursauts gamma et les microquasars. Les microquasars sont des systèmes stellaires binaires formés par un objet compact accrétant la matière d'une étoile compagnon. Ce transfert de masse est responsable de l'émission de rayons X, tandis que les forces magnétiques du plasma d'accrétion peuvent causer la création de jets relativistes qui sont observés par des télescopes radio grâce au rayonnement synchrotron non thermique émis par les particules chargées accélérées dans ces jets. Dans certains systèmes, la corrélation entre les courbes de lumière des rayons X et les courbes radio indique une interaction forte entre accrétion et éjection. Certains microquasars émettent également des rayons gamma de haute et très haute énergie (jusqu'à quelques dizaines de TeV). Dans ce travail de thèse, une recherche d'émission de neutrinos provenant de microquasars a été conduite avec une approche multi-messager (photon/neutrino). Les données des satellites RXTE/ASM et SWIFT/BAT, ainsi que du télescope gamma FERMI/LAT ont été étudiées afin de sélectionner les périodes dans lesquelles se produisent les jets relativistes. / The ANTARES collaboration has successfully built, deployed and is currently operating an underwater Cherenkov detector dedicated to high energy neutrino astronomy. The primary aim of the experiment is to detect cosmic sources of neutrinos in order to reveal the production sites of cosmic rays. Among the sources likely to be significant sources of neutrinos are those accelerating relativistic jets, like gamma ray bursts, active galactic nuclei and microquasars. Microquasars are binary systems formed by a compact object accreting mass from a companion star. The mass transfer causes the emission of X-rays, whereas the onset of magnetic forces in the accreting plasma can cause the acceleration of relativistic jets, which are observed by radio telescopes via their non-thermal synchrotron emission. In some systems, a correlation between X-ray and radio light curves indicates an interplay between accretion and ejection respectively. Some microquasars are also high energy and very high energy gamma ray emitters. In this thesis, a time dependent search for neutrino emission from microquasars was performed with a multi-messenger approach (photon/neutrino). The data from the X-ray monitors RXTE/ASM and SWIFT/BAT, and the gamma-ray telescope FERMI/LAT were used to select transient events in which the source was supposed to accelerate relativistic jets. The restriction of the analysis to the ejection periods allows a drastic reduction of atmospheric muon and neutrino background, and thus to increase the chances of a discovery. The search was performed with the ANTARES data taken between 2007 and 2010. Astronomie Neutrino Microquasar Binaires Antares Astronomy Neutrinos Microquasars Binaries Antares
199	[en] PHENOMENOLOGY OF NEUTRINOS AND PHYSICS BEYOND THE STANDARD MODEL / [pt] FENOMENOLOGIA DE NEUTRINOS E FÍSICA ALÉM DO MODELO PADRÃO FABIO ALEX PEREIRA DOS SANTOS 03 December 2012 (has links) [pt] Com o avanço na medida dos parâmetros responsáveis por oscilação de neutrinos, podemos dizer que hoje a física de neutrinos está entrando na era da precisão, o que nos permite explorar cenários além de massas e misturas de três sabores de neutrinos, ou seja, podemos procurar uma nova física que cause algum efeito subdominante, que não pode ser explicado por oscilação usual. Podemos citar a anomalia de antineutrinos de reator e anomalia de Gálio, ambas serão explicadas posteriormente no capítulo 3. Propomos uma solução alternativa para estas duas anomalias, baseado em um cenário com grandes dimensões extras. Exploramos também a capacidade de um experimento com neutrinos ultramonocromáticos produzidos via efeito Mossbauer, de detectar ou vincular alguns cenários de nova física além do modelo padrão. Os cenários que consideramos nesta tese são: neutrinos esteréis, estes sendo a extensão mais simples do modelo de três sabores; o cenário com grandes dimensões espaciais extras; descoerência quântica como física não padrão; e por último e não menos importante o cenário com neutrinos de massa variável. Mostramos também o impacto, se assumimos a existência destes cenários, na determinação dos parâmetros de oscilação Delta m2 31 e Teta 13. / [en] With advances in the measurements of the neutrino oscillation parameters, we can assume that neutrino physics is going to a precision era, as a consequence we can explore new scenarios beyond the standard mass and mixing with three neutrino flavors , that is, we can look for a new physics that affects in a subleading way and that can not be explained by the standard oscillation framework. For instance, the reactor antineutrino and Gallium anomalies, both anomalies will be discussed in chapter 3. We propose an explanation for these anomalies based on a scenario with large extra dimension. We also explore the capability of an experiment with ultramonochromatic neutrinos based on M ossbauer effect detects or constrains some new physics scenarios beyond the standard model. In this thesis we consider: sterile neutrinos, large extra dimensions, non standard quantum decoherence and mass varying neutrinos. We also show the impact on the determination of the standard oscillation parameters delta m2 31 and teta 13 if we assume non standard physics scenarios. [pt] FISICA [en] PHYSICS [pt] OSCILACAO DE NEUTRINOS [en] NEUTRINO OSCILLATIONS
200	Neutrino mass ordering studies with IceCube-DeepCore Wren, Steven January 2018 (has links) The IceCube Neutrino Observatory at the South Pole is the world's largest neutrino detector with over 1km^3 of instrumented Antarctic ice. While it has been primarily designed to observe astrophysical neutrinos, this size also allows it to collect vast quantities of atmospheric neutrinos. These high-statistics datasets allow for measurements of the properties of neutrinos, in particular the phenomena of neutrino oscillation. One of the outstanding questions in this field is that of the neutrino mass ordering (NMO). The Precision IceCube Next Generation Upgrade (PINGU) is a proposed low-energy extension to IceCube for which a determination of the NMO is a priority science goal. The current low-energy atmospheric neutrino experiment at the South Pole, DeepCore, has been successfully collecting data since 2011. In this thesis the potential of this existing data to determine the NMO has been explored. While it was not expected to have a large sensitivity, this work has explored a Feldman-Cousins treatment for converting the delta-chi^2 between the two discrete mass ordering hypotheses into the standard Gaussian significance metric. Using 2.7 years of data from the DeepCore detector, the inverted mass ordering was preferred at the level of 0.05sigma. The second aspect of this thesis was to study the impact of the systematic uncertainties on the NMO determination. This particular analysis was actually statistics-limited and so the only impactful systematic uncertainties were the parameters that govern atmospheric neutrino oscillations, theta_23 and Deltam^2_31. Therefore, to improve the NMO results, these parameters were constrained by including the global information on them in the fits, yielding a new NMO sensitivity of 0.29sigma. This new global fit also yields measurements of the oscillation parameters of Deltam^2_32,NO=(2.443+/-0.037)e-3eV^2 and sin^2theta_23,NO=0.442+0.026-0.018 for the hypothesis of the normal mass ordering and Deltam^2_32,IO=(-2.510+/-0.036)e-3eV^2 and sin^2theta_23,IO=0.579+0.019-0.021 for the hypothesis of the inverted mass ordering. In addition to the work on the neutrino mass ordering, this thesis also investigated two issues related to predictions of the flux of atmospheric particles. The first related to the treatment of the predictions of the atmospheric neutrino flux, provided in binned tables. Crucially, these contain values representative of the integral of the flux across that bin and so an integral-preserving interpolation must be used. One such method will be presented along with a discussion of how it performs in the two-dimensional case of the atmospheric neutrino flux. The second issue related to quantifying uncertainties on the background muon distributions observed with the IceCube detector coming from the uncertainties on the initial cosmic ray flux. This involved performing a global fit on the available cosmic ray flux measurements and then propagating these uncertainties in to the muon distributions. To finalise this section, the exact manner in which these uncertainties can be included in the physics analyses of IceCube will be discussed. 500

Search results