Global ETD Search

1	Study of thermal neutron flux from SuperKEKB in the Belle II commissioning detector Dejong, Samuel Rudy 31 May 2017 (has links) The Belle II detector is designed to collect data from the high luminosity electron-positron (e$^+$e$^-$) collisions of the SuperKEKB collider. It will explore the flavour sector of particle physics through precision measurements. The backgrounds of particles induced by the electron and positron beams will be much higher than in any previous \epem collider. It is important that these backgrounds be well understood in order to ensure appropriate measures are taken to protect the Belle II detector and minimize the impact of the backgrounds. In February 2016 electron and positron beams were circulated through the two 3 km vacuum pipe rings without being brought into collision during `Phase I' of SuperKEKB commissioning. Beam backgrounds were measured using Belle II's commissioning detector, BEAST II. BEAST II is composed of several small subdetectors, including helium-3 thermal neutron detectors. The BEAST II thermal neutron detector system and results from its Phase I running are presented in this dissertation. The Phase I experiment studies beam-gas interactions, where beam particles collide with residual gas atoms in the beampipes, and beam-beam interactions, where beam particles interact with each other. Simulations of these two types of backgrounds were performed using the Strategic Accelerator Design (SAD) and GEometry And Tracking (GEANT4) software packages. A method to account for the composition of the gas in the beampipes was developed in order to correctly analyse the beam-gas component of the background. It was also determined that the thermal neutron rates in the data on the positron beam were 2.18$^{+0.44}_{-0.42}$ times higher than the simulation of beam-gas interactions and 2.15$^{+0.34}_{-0.33}$ times higher for beam-beam interactions. The data on the electron beam were 1.32$^{+0.56}_{-0.36}$ times higher for beam-gas interactions and 1.91$^{+0.54}_{-0.48}$ time higher for beam-beam interactions. The impact of these studies on Belle II is discussed. / Graduate / samdejong86@gmail.com Physics particle physics Belle II BEAST II Helium-3 Thermal neutrons Beam Background
2	Radiation and background levels in a CLIC detector due to beam-beam effects Sailer, Andre 10 January 2013 (has links) Der Kompakte Linearbeschleuniger CLIC, ist ein Konzept für einen zukünftigen Elektron– Positron Beschleuniger mit einer Schwerpunktsenergie von 3 TeV. Die hohen Ladungsdichten, verursacht durch kleine Strahlgrößen, und die hohe Strahlenergie am CLIC, führen zur Produktion einer großen Menge von Teilchen durch Strahl-Strahl-Wechselwirkungen. Ein großer Teil dieser Teilchen wird den Detektor ohne Wechselwirkung verlassen, aber eine signifikante Menge Energie wird dennoch im Vorwärtsbereich des Detektors deponiert. Dadurch werden Sekundärteilchen erzeugt, von denen Einige Untergrund im Detektor verursachen werden. Es werden auch einige Teilchen mit inhärent großem Polarwinkel erzeugt, die direkt Untergrund in den Spurdetektoren und Kalorimetern verursachen können. Die Hauptursache von Untergrund im Detektor, entweder direkt oder durch Sekundärteilchen, sind inkohärente e+e− Paare und Teilchen aus hadronischen Zwei-Photon Ereignissen. Die Untergrund- und Strahlungspegel im Detektor müssen bestimmt werden, um zu untersuchen, ob ein Detektor mit den Untergrundbedingungen bei CLIC zurechtkommen kann. Mit Hilfe von Simulation der inkohärenten Paare in dem auf GEANT4 basierendem Programm MOKKA, wird die Geometrie eines auf Detektors für CLIC optimiert um den Untergrund im Vertexdetektor zu minimieren. In diesem optimiertem Detektor werden die Untergrund- und Strahlungspegel durch inkohärente e+e− Paare und hadronischen Zwei-Photon Ereignissen bestimmt. Des Weiteren wird die Möglichkeit untersucht, ob Schauer von hochenergetischen Elektron bei kleinen Polarwinkeln im BeamCal zu identifizieren sind. / The high charge density—due to small beam sizes—and the high energy of the proposed CLIC concept for a linear electron–positron collider with a centre-of-mass energy of up to 3 TeV lead to the production of a large number of particles through beam-beam interactions at the interaction point during every bunch crossing (BX). A large fraction of these particles safely leaves the detector. A still significant amount of energy will be deposited in the forward region nonetheless, which will produce secondary particles able to cause background in the detector. Furthermore, some particles will be created with large polar angles and directly cause background in the tracking detectors and calorimeters. The main sources of background in the detector, either directly or indirectly, are the incoherent e+e− pairs and the particles from gamma gamma to hadron events. The background and radiation levels in the detector have to be estimated, to study if a detector is feasible, that can handle the Compact Linear Collider (CLIC) background conditions. Based on full detector simulations of incoherent e+e− pairs with the GEANT4 based MOKKA program, the detector geometry of a CLIC detector is optimised to minimise the background in the vertex detector. Following the optimisation of the geometry, the background and radiation levels for incoherent pairs and gamma gamma to hadron events are estimated. The possibility of identifying high energy electron showers with the most forward calorimeter, the BeamCal, is investigated. CLIC Linear Beschleuniger Strahl-Strahl Wechselwirkung Detektor Optimierung CLIC Compact Linear Collider beam-beam background detector optimisation 530 Physik 29 Physik, Astronomie ddc:530
3	Trajectomètrie dans le cadre du projet européen AIDA / Tracking in the context of the European project AIDA Cousin, Loic 17 September 2015 (has links) Ce travail se place dans le contexte du détecteur de vertex (VXD) composé de capteurs CMOS pour l'ILC, et dans celui du télescope en faisceau du projet européen AIDA. La thèse inclut les tests en faisceau des éléments du télescope AIDA : les super-plans SALAT et les échelles double faces PLUME. Elle questionne la valeur ajoutée en terme d'alignement, des couches double faces de capteurs CMOS pour le VXD de l'ILD. Une nouvelle méthode d'alignement autonome de chacune des 3 double couches du VXD grâce aux mini-vecteurs construits sur chaque zone de recouvrement inter-échelle est proposée et a été testée avec des particules de haute impulsion. Cependant, seules les particules du bruit de fond faisceau, de plus basses impulsions, permettent l'obtention d'une statistique suffisante pour cet alignement. Ce bruit de fond a alors été étudié et une estimation des taux d'occupation des capteurs du VXD a conduit à une ré-estimation des vitesses de lecture des capteurs de chaque couche du VXD. / This work was conducted in the context of a vertex detector (VXD) composed of CMOS sensors for ILD and in the context of the beam telescope of the european project AIDA. The provides the results of beam tests for the new telescope components : the SALAT super-planes and the PLUME double sided ladders. The thesis adresses the added value in terms of alignment, of double sided layers of CMOS sensors for the VXD of ILD. A new standalone alignment method of each of the three double sided layers of VXD with the mini-vectors built on each overlapping zone between the consecutive ladders is analysed. Such alignment was validated with high momentum particles. However, only the beam background particles, with lower momentum, can provide the minimum statistic for this kind of alignment. Thus, the beam background noise was studied and the occupancy rate of the VXD sensors was studied. This led to a reassessment of the readout speed for the sensors of each layer of the VXD. Détecteur de vertex Trajectométrie Capteurs CMOS (CPS) International Linear Collider (ILC) Alignement Bruit de fond faisceau Vertex Detector Tracking CMOS pixel sensor (CPS) International Linear Collider (ILC) Alignment Beam Background 539.7

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