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Computational workflow optimization for magnetic fluctuation measurements of 3D nano-tetrapods
(2021)
The detailed understanding of micro–and nanoscale structures, in particular their magnetization dynamics, dominates contemporary solid–state physics studies. Most investigations already identified an abundance of phenomena in one–and two–dimensional nanostructures. The following thesis focuses on the magnetic fingerprint of three–dimensional CoFe nano–magnets, specifically the temporal development of their hysteresis loop. These nano–magnets were grown in a tetrahedral pattern on top of a highly susceptible home–build GaAs/AlGaAs micro–Hall sensor using focused electron beam induced deposition (FEBID).
During the measurements, utmost efforts were employed to exemplify current best research practices. The data life cycle of the present thesis is based upon open–source data science tools and packages. Data acquisition and analysis required self–written automated algorithms to handle the extensive quantity of data. Existing instrumental-controlling software was improved, and new Python packages were devised to analyze and visualize the gathered data. The open–source Python data analysis framework (ana) was developed to facilitate computational reproducibility. This framework transparently analyses and visualizes the gathered data automatically using Continuous Analysis tools based on GitLab and Continuous Integration. This automatization uses bespoke scripts combined with virtualization tools like Docker to facilitate reproducible and device–independent results.
The hysteresis loops reveal distinct differences in subsequently measured loops with identical initial experimental parameters, originating from the nano–magnet’s magnetic noise. This noise amplifies in regions where switching processes occur. In such noise–prone regions, the time–dependent scrutinization reveals presumably thermally induced metastable magnetization states. The frequency–dependent power spectral density uncovers a characteristic 1/f² behavior at noise–prone regions with metastable magnetization states.
During RUN3 (2021-2023) of the Large Hadron Collider, the Time Projection Chamber (TPC) of ALICE will be operated with quadruple stacks of Gas Electron Multipliers (GEMs). This technology will allow to overcome the rate limitation due to the gated operation of the Multi-Wire Proportional Chambers (MWPCs) used in RUN1 (2009-2013) and RUN2 (2015-2018).
As part of the Upgrade project, long-term irradiation tests, so called "ageing tests", have been carried out. A test setup with a detector using a quadruple stack of 10x10cm2 GEMs was built and operated in Ar-CO2 and Ne-CO2-N2 gas mixtures. The detector performance such as gas gain and energy resolution were monitored continuously. In addition, outgassing tests of materials used for the assembly process of the upgraded TPC were performed. To reach the expected dose of the GEM-based TPC, the detector was operated at much higher gains than the TPC. It was found, that the GEMs could keep their performance within the projected lifetime of the TPC. Most of the tested materials showed no negative impact on the detector. For the tested epoxy adhesive no certain conclusion could be drawn.
At much higher doses than expected for the upgraded TPC, a new phenomenon was observed, which changed the hole geometry of the GEMs and led to a degradation of the energy resolution. Even though its occurrence is not expected during the lifetime of the GEM-based TPC, simulations were carried out to study this effect more systematically. The simulations confirmed, that a change of the hole geometries of the GEMs, lead to an increase of the local gain variation, which results in a decrease of the energy resolution.
Furthermore the effect of methane as quench gas on GEMs was studied, even though this gas is not foreseen to be used in the TPC. From ageing tests with single-wire proportional counters it is well known that hydrocarbons are produced in the plasma of the avalanches, which cover the electrodes and lead to a degradation of the detector performance. Even though GEMs have a quite different geometry, the ageing tests showed, that also this technology tends to methane-induced ageing. A loss of gas gain as well as a degradation of the energy resolution due to deposits on the electrodes was monitored. A qualitative and quantitative comparison between ageing in GEMs and proportional counters was performed.
In thesis I investigate the possibility that at the smallest length scale (Planck scale) the very notion of "dimension" needs to be revisited. Due to "quantum effects" spacetime might become very turbulent at these scales and properties like those of "fractals" emerge, including a "scale dependent dimension". It seems that this "spontaneous dimensional reduction" and the appearance of a minimal physical length are very general effects that most approaches to quantum gravity share. Main emphasis is given to the"spectral dimension" and its calculation for strings and p-branes.
In this thesis, Planck size black holes are discussed. Specifically, new families of black holes are presented. Such black holes exhibit an improved short scale behaviour and can be used to implement gravity self-complete paradigm. Such geometries are also studied within the ADD large extra dimensional scenario. This allows black hole remnant masses to reach the TeV scale. It is shown that the evaporation endpoint for this class of black holes is a cold stable remnant. One family of black holes considered in this thesis features a regular de Sitter core that counters gravitational collapse with a quantum outward pressure. The other family of black holes turns out to nicely fit into the holographic information bound on black holes, and lead to black hole area quantization and applications in the gravitational entropic force. As a result, gravity can be derived as emergent phenomenon from thermodynamics.
The thesis contains an overview about recent quantum gravity black hole approaches and concludes with the derivation of nonlocal operators that modify the Einstein equations to ultraviolet complete field equations.
Die Druckmessung in Tieftemperatur-Vakuumsystemen stellt ein großes messtechnisches Problem dar. Für die in solchen Systemen auftretenden Drücke im UHV und XHV-Bereich werden meist Ionisationsmanometer vom Glühkathodentyp zur Druckmessung verwendet. Diese haben jedoch den entscheidenden Nachteil, dass durch die Verwendung einer Glühkathode zur Erzeugung freier Elektronen eine große Wärmelast in das System eingekoppelt wird. Dies führt zu einer Störung des thermischen Gleichgewichts und damit zu einer Verfälschung der Druckmessung. Weiterhin muss diese zusätzliche Wärmelast abgeführt werden, was vor allem bei kryogenen Vakuumsystemen einen erheblichen Mehraufwand darstellt.
Um dieses Problem zu umgehen, wurde ein Ionisationsmanometer entwickelt, dessen Glühkathode durch eine kalte Elektronenquelle ersetzt wurde. Der verwendete Feldemitter, eine kommerziell erhältliche CNT-Kathode, wurde gegenüber dem Anodengitter einer Extraktormessröhre positioniert. Mit diesem Aufbau wurden die Charakteristika von Kathode und Messröhre sowohl bei Raumtemperatur als auch unter kryogenen Vakuumbedingungen untersucht.
Dabei konnte gezeigt werden, dass die modifizierte Messröhre auch bei einer Umgebungstemperatur von 6 K ohne funktionale Einbußen betrieben werden kann und der gemessene Ionenstrom über mehrere Dekaden linear mit dem von einer Extraktormessröhre mit Glühkathode gemessenen Referenzdruck ansteigt. Des Weiteren konnte gezeigt werden, dass der Extraktor mit CNT-Kathode unter diesen kryogenen Bedingungen deutlich sensitiver auf geringe Druckschwankungen reagiert als sein Äquivalent mit Glühkathode.
Gabor lenses were invented for focusing hadron beams by the electric field of a confined electron column. A homogenous magnetic field created by a solenoid confines electrons in transverse direction while a potential well created by a cylindrical electrode system confines them longitudinally.
In this thesis the investigation and characterization of a nonneutral electron plasma (NNP) in a Gabor lens with a toroidal magnetic confinement and a 30 degree-bent anode is presented. Motivated by fundamental research on NNPs in this special environment, diagnostic methods were investigated to characterize the plasma. As a non-invasive method a PCO camera is placed in front of the experimental setup. A ring of 31 photodiodes is used inside the plasma for light intensity and distribution measurements. The experimental data is evaluated and the following results will be presented.
Cleaning an ion beam from unwanted fractions is crucial for intense ion beams. This thesis will explore separation methods using a collimation channel, electric and magnetic dipoles and a velocity selector for low intensity beams on an experimental basis. In addition, statistical data of degassing events during the commissioning of a pentode extraction system for beam energies from 20 - 120keV will be presented.
The aim of this thesis is finding a geometric configuration that allows electron insertion into a Gabor plasma lens in order to increase the density of the confined electrons and provide ignition conditions at parameters where ignition is not possible. First, simulations using CST and bender were conducted to investigate several geometric configurations in terms of their performance of inserting electrons manually. One particular design has been chosen as a basis for an experiment. In order to prepare the experiment, further simulations using the code bender have been conducted to investigate the density distribution that is formed inside the Gabor lens when inserting electrons transversally in compliance with the chosen design. Additionally, bender was used to investigate the impact of the initial electron energy on the distribution inside the lens. Simulations with and without space charge effects have shown a significant impact of the space charge effects on the resulting density dstribution. Therefore, space charge effects have proven to be the major electron redistribution process. A given electron source was characterised in order to find the performance under the conditions inside a Gabor lens. In particular, a transversal magnetic field that will be present in the experiment has to be compensated by shielding the inner regions of the source by a μ-metal layer. Using a μ-metal shield, transversal magnetic fields are sufficiently tolerable to perform measurements in a Gabor lens. Additionally, operating close to 100 eV electron energy yields a maximum in the emitted current. Adding a Wehnelt cylinder to the electron source furthermore improves the extracted current to roughly 1 mA. A test stand consisting of a newly designed anode for the Gabor lens, as well as a terminal for the electron source, was constructed. The electron source was thoroughly characterised in the environment of the Gabor lens and the ignition properties of the new system were evaluated. In further experiments, electron beam assisted ignition by increasing the residual gas pressure was observed and the impact of the position of the electron source on the ignition properties was investigated. In addition, ignition of a sub-critical state, that is a state consisting of potential, magnetic field and pressure that did not yet perform ignition by itself, was performed by increasing the extracted current from the electron source. Finally, the electron source was used to influence a pre-ignited plasma. The density was measured, which was increased by the use of the electron source in most cases. This project is part of the EDEN collaboration (Electron DENsity boosting) of the NNP Group at IAP Frankfurt with INFN institutes in Bologna and Catania.
Nichtinvasive Detektoren für ortsaufgelöste Strahlprofilmessungen gewinnen mit zunehmenden Strahlströmen und -energien immer mehr an Bedeutung. An der Universität Frankfurt im Institut für Angewandte Physik (IAP) wird ein “Figure Eight”-förmiger magnetostatischer Speichering mit Stellarator-Konfiguration (F8SR) entwickelt. Einige Aspekte der Strahldynamik in einem solchen Ring können mit einem experimentellen Aufbau am IAP untersucht werden. Die Herausforderung bei der Entwicklung eines Detektors an einem (F8SR) liegt auf der einen Seite darin den Strahl nichtinvasiv zu detektieren, und andererseits müssen magnetisch unempfindliche Komponenten für den Detektor ausgewählt werden. Dabei sollte der Detektor so flexibel sein, dass der Strahl entlang der Flugbahn transversal gemessen werden kann. In dieser Arbeit geht es um einen Detektor mit radial um den Strahl angeordneten Photodioden, mit deren Hilfe die strahlinduzierte Fluoreszenz detektiert wird und mit einem geeigneten Rekonstruktionsverfahren, Strahlposition und den Strahldurchmesser ermittelt werden kann. Die Messungen werden mit einem weiteren schon erprobten Detektor - einem Szintillationsschirm verglichen.
In dieser Arbeit wird der Strahltransport in einer Niederenergietransportsektion (LEBT) untersucht. Die Untersuchungen werden für die Betriebsmodi der im Aufbau befindlichen Neutronenquelle FRANZ an der Frankfurter Goethe-Universität durchgeführt. Hierbei wird die Akzeptanz eines Choppersystems nach der ersten Sektion des Transportwegs sowie die Akzeptanz des auf die zweite Sektion folgenden RFQ betrachtet und bestmöglich erfüllt. Die Auswirkungen durch die Raumladungswirkung des Ionenstrahls werden berücksichtigt, ebenso die mögliche thermische Belastung durch Strahlverlust an den Komponenten entlang des Strahlwegs. Weiterhin wird der Einfluss eines nicht optimierten Einschusses in den RFQ und die sich daraus ergebenden Strahleigenschaften am Ende des RFQs untersucht.