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Physics for particle detectors and p...

Windischhofer, Philipp.

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Physics for particle detectors and particle detectors for physics = timing performance of semiconductor detectors with internal gain and constraints on high-scale interactions of the Higgs Boson /

Record Type:	Electronic resources : Monograph/item
Title/Author:	Physics for particle detectors and particle detectors for physics/ by Philipp Windischhofer.
Reminder of title:	timing performance of semiconductor detectors with internal gain and constraints on high-scale interactions of the Higgs Boson /
Author:	Windischhofer, Philipp.
Published:	Cham :Springer Nature Switzerland : : 2023.,
Description:	xiv, 235 p. :ill. (some col.), digital ;24 cm.
Notes:	"Doctoral thesis accepted by University of Oxford, Oxford, UK."
[NT 15003449]:	Introduction -- The Formation of Electrical Signals in Particle Detectors -- The Statistics of Electron-hole Avalanches in Semiconductors -- Time Resolution and Efficiency of Single-photon Avalanche Diodes -- In-beam Performance of Single-photon Avalanche Diodes.
Contained By:	Springer Nature eBook
Subject:	Nuclear counters. -
Online resource:	https://doi.org/10.1007/978-3-031-39055-5
ISBN:	9783031390555

Physics for particle detectors and particle detectors for physics = timing performance of semiconductor detectors with internal gain and constraints on high-scale interactions of the Higgs Boson /
Windischhofer, Philipp.

Physics for particle detectors and particle detectors for physicstiming performance of semiconductor detectors with internal gain and constraints on high-scale interactions of the Higgs Boson /[electronic resource] :by Philipp Windischhofer. - Cham :Springer Nature Switzerland :2023. - xiv, 235 p. :ill. (some col.), digital ;24 cm. - Springer theses,2190-5061. - Springer theses..

"Doctoral thesis accepted by University of Oxford, Oxford, UK."

Introduction -- The Formation of Electrical Signals in Particle Detectors -- The Statistics of Electron-hole Avalanches in Semiconductors -- Time Resolution and Efficiency of Single-photon Avalanche Diodes -- In-beam Performance of Single-photon Avalanche Diodes.

Experimental particle physics is a science of many scales. A large number of physical processes spanning energies from meV to TeV must be understood for modern collider experiments to be designed, built, and conducted successfully. This thesis contributes to the understanding of phenomena across this entire dynamic range. The first half of this document studies aspects of low-energy physics that govern the operation of particle detectors, limit their performance, and guide the development of novel instrumentation. To formalise these aspects, classical electrodynamics is used to derive a general description of the formation of electrical signals in detectors, and ideas from quantum mechanics are applied to the study of charge avalanche amplification in semiconductors. These results lead to a comprehensive analytical characterisation of the time resolution and the efficiency of single-photon avalanche diodes, and isolate the most important design variables. They also reveal the applicability of these devices in precision timing detectors for charged particles, which is experimentally verified in a high-energy hadron beam. Large detector systems at hadron colliders probe fundamental physics at the energy frontier. In the second half, data collected with the ATLAS detector during Run 2 of the Large Hadron Collider are used to measure the cross-section for the production of a Higgs boson together with an electroweak boson as a function of the kinematic scale of the process. This measurement provides the finest granularity available to date for this process. It is highly informative of the structure of interactions beyond the direct kinematic reach of the experiment, and new limits are set on the couplings of such interactions within an effective field theory.

ISBN: 9783031390555

Standard No.: 10.1007/978-3-031-39055-5doiSubjects--Topical Terms:

1969269
Nuclear counters.

LC Class. No.: QC787.C6

Dewey Class. No.: 539.77

Physics for particle detectors and particle detectors for physics = timing performance of semiconductor detectors with internal gain and constraints on high-scale interactions of the Higgs Boson /
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245 1 0 $a Physics for particle detectors and particle detectors for physics $h [electronic resource] : $b timing performance of semiconductor detectors with internal gain and constraints on high-scale interactions of the Higgs Boson / $c by Philipp Windischhofer.
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300 $a xiv, 235 p. : $b ill. (some col.), digital ; $c 24 cm.
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500 $a "Doctoral thesis accepted by University of Oxford, Oxford, UK."
505 0 $a Introduction -- The Formation of Electrical Signals in Particle Detectors -- The Statistics of Electron-hole Avalanches in Semiconductors -- Time Resolution and Efficiency of Single-photon Avalanche Diodes -- In-beam Performance of Single-photon Avalanche Diodes.
520 $a Experimental particle physics is a science of many scales. A large number of physical processes spanning energies from meV to TeV must be understood for modern collider experiments to be designed, built, and conducted successfully. This thesis contributes to the understanding of phenomena across this entire dynamic range. The first half of this document studies aspects of low-energy physics that govern the operation of particle detectors, limit their performance, and guide the development of novel instrumentation. To formalise these aspects, classical electrodynamics is used to derive a general description of the formation of electrical signals in detectors, and ideas from quantum mechanics are applied to the study of charge avalanche amplification in semiconductors. These results lead to a comprehensive analytical characterisation of the time resolution and the efficiency of single-photon avalanche diodes, and isolate the most important design variables. They also reveal the applicability of these devices in precision timing detectors for charged particles, which is experimentally verified in a high-energy hadron beam. Large detector systems at hadron colliders probe fundamental physics at the energy frontier. In the second half, data collected with the ATLAS detector during Run 2 of the Large Hadron Collider are used to measure the cross-section for the production of a Higgs boson together with an electroweak boson as a function of the kinematic scale of the process. This measurement provides the finest granularity available to date for this process. It is highly informative of the structure of interactions beyond the direct kinematic reach of the experiment, and new limits are set on the couplings of such interactions within an effective field theory.
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