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Development of a high pressure xenon gas time projection chamber with a unique cellular readout structure to search for neutrinoless double beta decay / ニュートリノを伴わない二重ベータ崩壊探索のためのユニークなセル構造信号読み出し機構を持った高圧キセノンガスtime projection chamber の開発Pan, Sheng 25 May 2020 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第22627号 / 理博第4616号 / 新制||理||1663(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 市川 温子, 教授 中家 剛, 准教授 窪 秀利 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM
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A study of neutron pairing correlations using the 136Ba(p, t) reactionJespere Calderone, Nzobadila Ondze January 2020 (has links)
>Magister Scientiae - MSc / Observation of neutrinoless double beta decay (0 ) is currently the only
means by which one could establish the Majorana nature of neutrinos. Additionally,
such an observation would determine the absolute neutrino mass
scale. However, this requires that the matrix element for a given 0 decay
process is accurately calculated. The objective of this project is to provide
useful nuclear structure information that aim to improve future theoretical
calculations for the nuclear matrix element (NME) of 136Xe 0 decay to
136Ba. We studied neutron pairing correlations in 134Ba using the 136Ba(p; t)
reaction to stringently test the Bardeen-Cooper-Schrie er (BCS) approximation
in the A = 136 mass region. This is because many theoretical calculations
of the NME's for 0 decay are performed using the quasiparticle
random phase approximation (QRPA), which uses the BCS approximation
to describe the ground states of the even-even parent and daughter nuclei.
Our results show a signi cant fragmentation of the neutron-pair transfer to
excited 0+ states, implying a breakdown of the BCS approximation in this
mass region.
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Sensitivity enhancement of the CUORE experiment via the development of Cherenkov hybrid TeO₂ bolometers / Amélioration de la sensibilité de l'expérience CUORE par le développement de bolomètres de TeO₂ hybrides à “lumière CherenkovNovati, Valentina 21 November 2018 (has links)
CUORE est la plus grande expérience qui recherche la double désintégration bêta sans neutrino avec des bolomètres de TeO₂. La découverte de cette transition nucléaire aurait des conséquences décisives sur la scène actuelle de la physique. Les questions suivantes trouveraient une réponse : pourquoi la matière est-elle dominante dans l’Univers? Quelle est la masse du neutrino? Le neutrino est il un particule de Majorana ou de Dirac? Ce travail présente deux approches différentes pour l’amélioration de la sensibilité de CUORE en vue de sa prochaine phase : CUPID. Dans la première partie de ce travail, une étude du modèle thermique pour les bolomètres équipés avec des NTDs est présentée dans le but de mieux comprendre la réponse des détecteurs de CUORE. Les bolomètres sont des détecteurs extraordinaires utilisés pour un grand nombre d’applications en raison de leurs performances remarquables, mais leur modélisation et leur simulation sont loin d’être complètement comprises. Deux mesures ont été effectuées pour évaluer expérimentalement deux paramètres du modèle thermique : la conductance de la colle et celle entre les électrons et les phonons. Dans la deuxième partie de ce travail, la possibilité de détecter la faible lumière Cherenkov émise par le TeO₂ est étudiée à fin de rejeter des événements alpha, le fond principal de l’expérience CUORE. Le défi consiste dans la détection d’un signal de lumière de 100 eV à moyen d’un détecteur équipé avec un NTD qui a normalement un bruit de l’ordre de 100 eV. Cette question peut être résolue grâce à l’effet Neganov-Trofimov-Luke (NTL) qui a permis de baisser le seuil du détecteur de lumière et d'améliorer son rapport signal-sur-bruit. Cet effet exploite la présence d’un champ électrique pour amplifier les signaux thermiques des bolomètres. Le rejet complet du fond alpha a été prouvé avec un photo-bolomètre amélioré par l’effet NTL et couplé à un bolomètre de TeO₂ comme ceux utilisés par CUORE. Une solution convaincante pour le rejet de fond alpha a été démontrée en vue de l’expérience CUPID. / CUORE is the first tonne-scale experiment searching for the neutrinoless double beta decay with TeO₂ bolometers. The discovery of this nuclear transitionwould have decisive consequences on the present physics scene. The following questions would find an answer: why is matter dominant in the Universe? which is the neutrino mass? has the neutrino a Majorana or a Dirac nature? This work presents two different approaches for the enhancement of the CUORE sensitivity with a view to its upgrade: the CUPID experiment. In the first part, a study of the thermal model describing NTD-based bolometers is presented with the objective to achieve a better comprehension of the response of the CUORE detectors. Bolometers are amazing detectors used for a large number of applications because of their impressive high performance, but their modelisation and simulation is far to be completely understood. Two measurements have been performed for an experimental evaluation of two thermal-model parameters: the glue and the electron-phonon conductances. In the second part, the possibility to detect the tiny Cherenkov light emitted by TeO₂ to reject alpha events — the main background of the CUORE experiment — is studied. The challenge consists in the detection of a 100-eV light signal with a NTD-based light detector that usually is characterised by a baseline noise of the order of 100 eV. This issue is solved with the employment of the Neganov-Trofimov-Luke (NTL) effect to lower the energy threshold of the light detector and improve its signal-to-noise ratio. This effect exploits the presence of an electric field to amplify bolometric thermal signals. The full rejection of the alpha background has been proved with one NTL assisted photo-bolometer coupled to a CUORE-size TeO₂ bolometer. A convincing solution for the alpha background rejection has been demonstrated with a view to the CUPID experiment.
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Monitorování energetické stupnice v neutrinovém experimentu KATRIN / Monitoring of the energy scale in the KATRIN neutrino experimentSlezák, Martin January 2016 (has links)
The question of the absolute mass scale of neutrinos is of particular interest for particle physics, astrophysics, and cosmology. The KATRIN experiment (KArlsruhe TRItium Neutrino experiment) aims to address the effective electron antineutrino mass from the shape of the tritium β-spectrum with an unprecedented sensitivity of 0.2 eV/c2 . One of the major systematic effects concerns the experimental energy scale, which has to be stable at the level of only a few parts in a million. For its calibration and monitoring the monoener- getic electrons emitted in the internal conversion of γ-transition of the metastable isotope 83m Kr will be extensively applied. The aim of this thesis is to address the problem of KA- TRIN energy scale distortions and its monitoring in detail. The source of electrons based on 83m Kr embedded in a solid as well as the source based on gaseous 83m Kr are studied. Based on the experimental results an approach for the continuous stability monitoring is proposed. 1
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The Tao and Zen of neutrinos: neutrinoless double beta decay in KamLAND-Zen 800Li, Aobo 30 September 2020 (has links)
Neutrinoless Double Beta Decay(0𝜈𝛽𝛽) is one of the major research interests in neutrino physics. The discovery of 0𝜈𝛽𝛽 would answer persistent puzzles in the Standard Model of Elementary Particles. KamLAND-Zen is one of the leading efforts in the search of 0𝛽𝛽 and has acquired data from 745 kg of ^{136}Xe over 224 live-days. This data is analyzed using a Bayesian approach consisting of a Markov Chain Monte Carlo (MCMC) algorithm. The implementation of the Bayesian analysis, which is the focal point of this dissertation, yields a 90\% Credible Interval at T^{0𝜈}_{1/2} = 7.03 × 10^{25} years. Finally, a machine learning event classification algorithm, based on a spherical convolutional neural network (spherical CNN) was developed to increase the T^{0𝜈}_{1/2} sensitivity. The classification power of this algorithm was demonstrated on a Monte Carlo detector simulation, and a data driven classifier was trained to reject crucial backgrounds in the 0𝜈𝛽𝛽 analysis. After implementing the spherical CNN, an increase in T^{0𝜈}_{1/2} sensitivity of 11.0% is predicted. These early studies pave the way for substantial improvements in future 0𝜈𝛽𝛽 analyses.
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Search for sterile neutrinos in β-decays / Recherche de neutrinos stériles dans les désintégrations βAltenmüller, Konrad Martin 10 October 2019 (has links)
Le travail présenté dans cette thèse porte sur la recherche de neutrino stérile à l'aide de désintégrations β dans les expériences SOX et TRISTAN. Le neutrino stérile est une particule hypothétique, solidement établi théoriquement, qui ne prendrait part à aucune interaction fondamentale, gravité mise à part. Étant entendu que le neutrino stérile se mélange avec les neutrinos actifs connus, l'existence de ces premiers peut être étudiée directement en laboratoire. L'expérience SOX a été conçue pour explorer l'existence d'un neutrino stérile d'une masse autour de l'électronvolt (eV). Un neutrino stérile avec une telle masse permettrait d'expliquer plusieurs anomalies observées à courte distance de sources (quelques mètres) lors de mesures d'oscillations de neutrinos de basses énergies (quelques MeV). SOX avait pour projet d'utiliser le détecteur de neutrinos solaire déjà existant Borexino, et d'observer un signal d'oscillation vers le stérile à l'intérieur même du volume actif du détecteur. La source radioactive de 5.5 PBq et positionnée à 8.5 m du centre du détecteur, émettrait des antineutrinos électroniques via la désintégration β du ¹⁴⁴Ce et du ¹⁴⁴Pr. Une des clés de l'observation de cette oscillation, est la connaissance précise de l'activité de la source. Une telle activité peut être déterminée en mesurant la chaleur dégagée par la source. C'est la raison pour laquelle l'INFN Genova et la TUM ont développé conjointement un calorimètre dédié. La chaleur dégagée par la radioactivité est alors captée par un échangeur puis transmise à un circuit d'eau étroitement contrôlé. Le calorimètre a été assemblé, optimisé puis étalonné avec succès. La perte de chaleur du circuit fut déterminée lors des mesures d'étalonnage grâce à un chauffage électrique. Des variations des conditions expérimentales et une isolation thermique sophistiquée ont permis d'opérer avec des pertes de chaleur négligeables. Il a ainsi été démontré que la puissance thermique de la source pouvait être estimée, en 5 jours seulement, avec une précision supérieure à 0,2%. Malheureusement, le programme SOX a dû être annulé. Le projet TRISTAN, quant à lui, tend à démontrer l'existence d'un neutrino stérile avec une masse de l'ordre du kilo-électronvolt (keV). Si le neutrino stérile à l'eV tente d'apporter une réponse aux différentes anomalies observées lors de mesures d'oscillation, le neutrino stérile au keV, en tant que potentiel candidat matière noire. Le projet TRISTAN cherche à mesurer l'empreinte de ce nouvel état de masse sur le spectre du tritium dans le cadre de l'expérience KATRIN. Cette dernière vise à déterminer la masse effective du neutrino (actif) en mesurant l'extrémité du spectre de tritium avec une excellente résolution et un faible taux de comptage. Une fois la mesure achevée, le détecteur de KATRIN sera modifié afin d'effectuer une mesure différentielle et intégrale de l'ensemble du spectre en tritium: c'est le projet TRISTAN. Le détecteur actuel sera remplacé par un nouveau détecteur de silicium à dérive (SDD) de 3500 pixels permettant une résolution de 3% à 6 keV et pouvant supporter un taux de comptage montant jusqu'à 10⁸ coups par seconde, activité maximum attendue. Un prototype a été testé avec succès et une première mesure de tritium a été réalisé au spectromètre de masse neutrino Troitsk afin d'étudier les erreurs systématiques et de développer des méthodes d'analyses pertinentes. Un premier ajustement cohérent du spectre tritium différentiel acquis lors de cette installation, a démontré la faisabilité du projet. TRISTAN lui-même est toujours en cours de développement mais les caractérisations du détecteur et les études de systématiques sont plus qu'encourageantes pour la poursuite du projet. La première investigation de neutrino stérile avec le détecteur de TRISTAN sur le site de KATRIN est prévue après la mesure de masse, en cours à Karlsruhe, aux alentours de 2024. / The work presented in this thesis is about the sterile neutrino search with the two experiments SOX and TRISTAN based on the β-decay. Sterile neutrinos are theoretically well motivated particles that do not participate in any fundamental interaction except for the gravitation. With the help of these particles one could elegantly explain the origin of the neutrino mass, dark matter and the matter-antimatter asymmetry in the universe. As sterile neutrinos can mix with the known active neutrinos, they could be discovered in laboratory searches. The SOX experiment was designed to search for a sterile neutrino with a mass in the eV-range. This particular mass range is motivated by several anomalous observations at short-baseline neutrino experiments that could be explained by an additional oscillation with a length in the order of meters that arises from an eV-scale sterile neutrino. For SOX it was planned to use the existing Borexino solar neutrino detector to search for an oscillation signal within the detector volume. The neutrinos are emitted from a 5.5 PBq electron-antineutrino source made of the β-decaying isotopes ¹⁴⁴Ce and ¹⁴⁴Pr, located at 8.5 m distance from the detector center. For the analysis of the signal it is crucial to know the source activity. This parameter is determined by measuring the decay heat of the source with a thermal calorimeter that was developed by TUM and INFN Genova. The decay heat is measured through the temperature increase of a well-defined water flow in a heat exchanger that surrounds the source. The calorimeter was assembled, optimized and characterized. Heat losses were determined through calibration measurements with an electrical heat source. Adjustable measurement conditions and an elaborate thermal insulation allowed an operation with negligible heat losses. It was proven that the power of a decaying source can be measured with <0.2% uncertainty in a single measurement that lasts ~5 days. Unfortunately the SOX experiment was canceled after a technological problem rendered the source production with the required activity and purity impossible. The TRISTAN project is an attempt to discover sterile neutrinos with masses in the order of keV. In contrast to eV-scale sterile neutrinos that are motivated by several anomalies observed in terrestrial experiments, the existence of sterile neutrinos with masses in the keV range could resolve cosmological and astrophysical issues, as they are dark matter candidates. The TRISTAN project is an extension of the KATRIN experiment to search for the signature of keV-scale sterile neutrinos in the tritium β-spectrum. KATRIN itself is attempting to determine the effective neutrino mass by measuring the end point of the tritium spectrum at low counting rates. The KATRIN setup will be modified after the neutrino mass measurements are finished to conduct a differential and integral measurement of the entire tritium spectrum. This project is called TRISTAN. The current detector will be replaced by a novel 3500-pixel silicon drift detector system that has an outstanding energy resolution of a few hundred eV and can handle rates up to 10⁸ counts per second as they occur when the entire spectrum is scanned. Prototype detectors were successfully tested and first tritium data was taken at the Troitsk ν-mass spectrometer to study systematic effects and develop analysis methods. A successful fit of the differential tritium spectrum proved the feasibility of this approach. TRISTAN itself is still at an early stage, but the detector development and systematic studies are well on track and delivered so far encouraging results. The sterile neutrino search is scheduled after the KATRIN neutrino mass program is finished in ~2024.
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Characterization of isomeric states in neutron-rich nuclei approaching N = 28Ogunbeku, Timilehin Hezekiah 08 December 2023 (has links) (PDF)
The investigation of isomeric states in neutron-rich nuclei provides useful insights into the underlying nuclear configurations, and understanding their occurrence along an isotopic chain can inform about shell evolution. Recent studies on neutron-rich Si isotopes near the magic number N = 20 and approaching N = 28 have revealed the presence of low-lying states with intruder configurations, resulting from multiple-particle, multiple-hole excitations across closed shell gaps. The characterization of these states involves measuring their half-lives and transition probabilities.
In this study, a new low-energy (7/2−1) isomer at 68 keV in 37Si was accessed via beta decay and characterized. To achieve this, radioactive 37Al and 38Al ions were produced through the projectile fragmentation reaction of a 48Ca beam and implanted into a CeBr3 detector, leading to the population of states in 37Si. The 68-keV isomer was directly populated in the beta-delayed one neutron emission decay of implanted 38Al ions. Ancillary detector arrays comprising HPGe and LaBr3(Ce) detectors were employed for the detection of beta-delayed gamma rays. The choice of detectors was driven by their excellent energy and timing resolutions, respectively.
The beta-gamma timing method was utilized to measure the half-life of the new isomeric state in 37Si. This dissertation also discusses other timing techniques employed to search for and characterize isomeric states following beta decay of implanted ions. Notably, the half-life of the newly observed (7/2−1) isomeric state in 37Si was measured to be 9.1(7) ns. The half-life of the previously observed closely-lying (3/2−1) state at 156 keV was determined to be 3.20(4) ns, consistent with previously reported values. Reduced ground-state transition probabilities associated with the gamma-ray decay from these excited states were in agreement with results obtained from shell model calculations.
In addition to the investigation of isomeric states in 37Si, isomeric 0+ states in 34Si and 32Mg nuclei belonging to the N = 20 “island of inversion” were characterized and searched for, respectively. The isomeric 0+ state in 34Si was populated following the beta decay of implanted 34Mg ions and its 34Al daughter nucleus. Similarly, the 0+ state in 32Mg was searched for via the beta-delayed one neutron emission decay of implanted 33Na ions.
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Spectroscopy of the A = 33 Isobars in the Island of InversionRichard, Andrea L. 11 July 2018 (has links)
No description available.
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Development of a large-sized high-pressure xenon gas time projection chamber for neutrinoless double beta decay search / ニュートリノを伴わない二重ベータ崩壊探索のための大型高圧キセノンガスタイムプロジェクションチェンバーの開発Nakamura, Kazuhiro 23 May 2022 (has links)
京都大学 / 新制・課程博士 / 博士(理学) / 甲第24073号 / 理博第4840号 / 新制||理||1692(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)教授 中家 剛, 教授 永江 知文, 准教授 WENDELL Roger / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM
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Pulse shape simulation and search for rare decays with the COBRA extended demonstratorChu, Yingjie 29 August 2024 (has links)
Double beta decay is a powerful tool to investigate the properties of the neutrino and of the weak interaction. Studying characteristics of this decay is very challenging because
of its long half-life and interfering natural backgrounds. One experiment aiming to investigate double beta decay is the COBRA experiment located at the Gran Sasso
Underground Laboratory. COBRA uses room temperature CdZnTe semiconductor detectors that intrinsically contain multiple double beta decay candidates. The previous COBRA Demonstrator had a relatively high background level and thus is not competitive for double beta decay searches. With the objective of reducing the background as well as increasing the signal sensitivity, the experiment was upgraded using large CdZnTe detectors with a novel electrode design.
This work focuses on the study of the new detectors. A pulse shape simulation based on COMSOL and Monte Carlo is developed with the goal of characterizing the new detectors. This simulation framework is also part of a newly developed pulse shape discrimination to suppress background.
Applying those analysis cuts the background index improves by a factor of 23 compared to the previous setup. Furthermore, the 2νββ-decay of 116Cd is investigated using data with an exposure of 0.18 kg·yr. The potential for measuring the excited state transition of this decay is also explored.
Apart from the double beta decay investigations, a study of the charge non-conserving decay of 113Cd will be presented. The new half-life limit helps to constrain the theoretical presumptions for this exotic decay process.
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