TY  - THES
A1  - Weber, Stefan
T1  - Simulation Studies on the New Small Wheel Shielding of the ATLAS Experiment and Design and Construction of a Test Facility for Gaseous Detectors
T1  - Simulationsstudien zur New Small Wheel Abschirmung des ATLAS Experiments und Entwurf und Konstruktion eines Teststandes für Gasdetektoren
N2  - In this thesis two main projects are presented, both aiming at the overall goal
of particle detector development. In the first part of the thesis detailed shielding
studies are discussed, focused on the shielding section of the planned New Small
Wheel as part of the ATLAS detector upgrade. Those studies supported the discussions
within the upgrade community and decisions made on the final design of
the New Small Wheel. The second part of the thesis covers the design, construction
and functional demonstration of a test facility for gaseous detectors at the
University of Würzburg. Additional studies on the trigger system of the facility are
presented. Especially the precision and reliability of reference timing signals were
investigated.
N2  - In dieser Arbeit werden zwei Projekte vorgestellt, welche beide das gemeinsame
Ziel der Entwicklung von Teilchendetektoren verfolgen. Im ersten Teil der Arbeit
werden ausführliche Simulationsstudien zur Abschirmung behandelt, die sich auf
die Abschirmungsbereiche des geplanten New Small Wheels als Teil der ATLAS-Detektor
Verbesserungen konzentrieren. Diese Studien unterstützten die Diskussionen
innerhalb der Upgrade-Gemeinschaft und Entscheidungen, welche für die
endgültige Kostruktionsplanung des New Small Wheels getroffen wurden. Der
zweite Teil der Arbeit umfasst die Konstruktion, den Aufbau sowie den Funktionsnachweis
eines Teststandes für Gasdetektoren an der Universität Würzburg.
Ebenfalls werden Studien über das Triggersystems des Teststandes dargestellt. Insbesondere
wurden die Präzision und Verlässlichkeit von Referenzzeitsignalen untersucht.
KW  - Teilchendetektor
KW  - Abschirmung
KW  - Simulation
KW  - test facility
KW  - New Small Wheel
KW  - Teststand
KW  - Gasionisationsdetektor
KW  - European Organization for Nuclear Research. ATLAS Collaboration
KW  - Computersimulation
Y1  - 2016
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-133084
ER  - 
TY  - INPR
A1  - Reiss, Harald
T1  - Physical time and existence of time holes in non-transparent media
N2  - The analysis presented in this paper applies to experimental situations where observers or objects to be studied (both stationary, with respect to each other) are located in environments the optical thickness of which is strongly different. By their large optical thickness, non-transparent media are clearly distinguished from their transparent counterparts. Non-transparent media comprise thin metallic films, packed or fluidised beds, the Earth’s crust, and even dark clouds and other cosmological objects. As a representative example, a non-transparent slab is subjected to transient disturbances, and a rigorous analysis is presented whether physical time reasonably could be constructed under such condition. The analysis incorporates mapping functions that correlate physical events, e, in non-transparent media, with their images, f(e), tentatively located on a standard physical time scale. The analysis demonstrates, however, that physical time, in its rigorous sense, does not exist under non-transparency conditions. A proof of this conclusion is attempted in three steps: i) the theorem “there is no time without space and events” is accepted, (ii) images f[e(s,t)] do not constitute a dense, uncountably infinite set, and (iii) sets of images that are not uncountably infinite do not create physical time but only time-like sequences. As a consequence, mapping f[e(s,t)] in non-transparent space does not create physical analogues to the mathematical structure of the ordered, dense half-set R+ of real numbers, and reverse mapping, f-1f[e(s,t)] would not allow unique identification and reconstruction of original events from their images. In these cases, causality and determinism, as well as invariance of physical processes under time reversal, might be violated. Existence of time holes could be possible, as follows from the sequence of images, f[e(s,t)], that is not uncountably infinite, in contrast to R+. Practical impacts are expected for understanding physical diffusion-like, radiative transfer processes, stability models to protect superconductors against quenchs or for description of their transient local pair density and critical currents. Impacts would be expected also in mathematical formulations (differential equations) of classical physics, in relativity and perhaps in quantum mechanics, all as far as transient processes in non-transparent space would be concerned. An interesting problem is whether temporal cloaking (a time hole) in a transparent medium, as very recently reported in the literature, can be explained by the present analysis. The analysis is not restricted to objects of laboratory dimensions: Because of obviously existing radiation transfer analogues, it is tempting to discuss consequences also for much larger structures in particular if an origin of time is postulated.
KW  - Strahlungstransport
KW  - Zeitrichtung
KW  - Supraleiter
KW  - Computersimulation
KW  - Non-transparency
KW  - disturbance
KW  - physical time
KW  - time hole
Y1  - 2012
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-67268
N1  - Von diesem Artikel gibt es eine überarbeitete Version unter urn:nbn:de:bvb:20-opus-73554.
ER  - 
TY  - THES
A1  - Wenisch, Jan
T1  - Ferromagnetic (Ga,Mn)As Layers and Nanostructures: Control of Magnetic Anisotropy by Strain Engineering
T1  - Ferromagnetische (Ga,Mn)As Schichten und Nanostrukturen: Kontrolle der magnetischen Anisotropie durch Manipulation der Kristallverspannung
N2  - This work studies the fundamental connection between lattice strain and magnetic anisotropy in the ferromagnetic semiconductor (Ga,Mn)As. The first chapters provide a general introduction into the material system and a detailed description of the growth process by molecular beam epitaxy. A finite element simulation formalism is developed to model the strain distribution in (Ga,Mn)As nanostructures is introduced and its predictions verified by high-resolution x-ray diffraction methods. The influence of lattice strain on the magnetic anisotropy is explained by an magnetostatic model. A possible device application is described in the closing chapter.
N2  - Die vorliegende Arbeit untersucht den fundamentalen Zusammenhang zwischen Gitterverspannung und magnetischer Anisotropie in dem ferromagnetischen Halbleiter (Ga,Mn)As. Die ersten Kapitel bieten eine allgemeine Einleitung in das Materialsystem und eine detaillierte Beschreibung des Wachstumsprozesses mittels Molekularstrahlepitaxie. Eine Finite-Elemente Simulation wird entwickelt, um die Verteilung der Gitterverspannung in (Ga,Mn)As Nanostrukturen zu modellieren. Die daraus abgeleiteten Vorhersagen werden mittels hochauflösender Röntgenbeugung bestätigt. Der Einfluss der Gitterverspannung auf die magnetische Anisotropie wird anhand eines magnetostatischen Modells erklärt. Das abschließende Kapitel gibt einen Ausblick auf eine mögliche praktische Anwendung der beschriebenen Phänomene.
KW  - Magnetischer Halbleiter
KW  - Drei-Fünf-Halbleiter
KW  - Ferromagnetismus
KW  - Magnetoelektronik
KW  - Bandstrukturberechnung
KW  - Molekularstrahlepitaxie
KW  - Elastische Spannung
KW  - Computersimulation
KW  - Röntgenbeugung
KW  - GaMnAs
KW  - Ferromagnetic Semiconductors
KW  - Magnetic Anisotropy
KW  - Molecular Beam Epitaxy
KW  - Strain
Y1  - 2008
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-34552
ER  -