Institutes
Refine
Year of publication
- 2022 (23) (remove)
Document Type
- Doctoral Thesis (23) (remove)
Has Fulltext
- yes (23)
Is part of the Bibliography
- no (23)
Keywords
- HADES (2)
- Accelerator (1)
- Activation experiment (1)
- Auditory cortex (1)
- Binary (1)
- Black hole (1)
- Cross section (1)
- Flow (1)
- Functional Renormalization Group (1)
- Heavy-ion Collisions (1)
Institute
- Physik (23)
In this thesis, the flow coefficients vn of the orders n = 1 − 6 are studied for protons and light nuclei in Au+Au collisions at Ebeam = 1.23 AGeV, equivalent to a center-of-mass energy in the nucleon-nucleon system of √sNN = 2.4 GeV. The detailed multi-differential measurement is performed with the HADES experiment at SIS18/GSI. HADES, with its large acceptance, covering almost full azimuth angle, combined with its high mass-resolution and good particle-identification capability, is well equipped to study the azimuthal flow pattern not only for protons, deuterons, and tritons but also for charged pions, kaons, the φ-mesons, electrons/positrons, as well as light nuclei like helions and alphas. The high statistics of more than seven billion Au-Au collisions recorded in April/May 2012 with HADES enables for the first time the measurement of higher order flow coefficients up to the 6th harmonic. Since the Fourier coefficient of 7th and 8th order are beyond the statistical significance only an upper bound is given. The Au+Au collision system is the largest reaction system with the highest particle multiplicities, which was measured so far with HADES. A dedicated correction method for the flow measurement had to be developed to cope with the reconstruction in-efficiencies due to occupancies of the detector system. The systematical bias of the flow measurement is studied and several sources of uncertainties identified, which mainly arise from the quality selection criteria applied to the analyzed tracks, the correction procedure for reconstruction inefficiencies, the procedures for particle identification (PID) and the effects of an azimuthally non-uniform detector acceptance. The systematic point-to-point uncertainties are determined separately for each particle type (proton, deuteron and triton), the order of the flow harmonics vn, and the centrality class. Further, the validity of the results is inspected in the range of their evaluated systematic uncertainties with several consistency checks. In order to enable meaningful comparisons between experimental observations and predictions of theoretical models, the classification of events should be well defined and in sufficiently narrow intervals of impact parameter. Part of this work included the implementation of the procedure to determine the centrality and orientation of the reaction.
In the conclusion the experimental results are discussed, including various scaling properties of the flow harmonics. It is found that the ratio v4/v2 for protons and light nuclei (deuterons and tritons) at midrapidity for all centrality classes approaches values close to 0.5 at high transverse momenta, which was suggested to be indicative for an ideal hydrodynamic behaviour. A remarkable scaling is observed in the pt dependence of v2 (v4) at mid-rapidity of the three hydrogen isotopes, when dividing by their nuclear mass number A (A^2) and pt by A. This is consistent with naive expectations from nucleon coalescence, butraises the question whether this mass ordering can also be explained by a hydrodynamical-inspired approach, like the blast-wave model. The relation of v2 and v4 to the shape of the initial eccentricity of the collision system is studied. It is found that v2 is independent of centrality for all three particle species after dividing it by the averaged second order participant eccentricity v2/⟨ε2⟩. A similar scaling is shown for v4 after division by ⟨ε2⟩^2.
This Ph. D. thesis with the title "Characterisation of laser-driven radiation beams: Gamma-ray dosimetry and Monte Carlo simulations of optimised target geometry for record-breaking efficiency of MeV gamma-sources" is dedicated to the study of the acceleration of electrons by intense sub-picosecond laser pulses propagating in a sub-millimeter plasma with near-critical electron density (NCD) and resulting generation of the gamma bremsstrahlung and positrons in the targets of different materials and thickness.
Laser-driven particle acceleration is an area of increasing scientific interest since the recent development of short pulse, high-intensity laser systems. The interaction of intense high-energy, short-pulse lasers with solid targets leads to the production of high-energy electrons in the relativistic laser intensity regime of more than 1018 W /cm2. These electrons play the leading role in the first stage of the interaction of laser with matter, which leads to the creation of laser sources of particles and radiation. Therefore, the optimisation of the electron beam parameters in the direction of increasing the effective temperature and beam charge, together with a slight divergence, plays a decisive role, especially for further detection and characterisation of laser-driven photon and positron beams.
In the context of this work, experiments were carried out at the PHELIX laser system (Petawatt High-Energy Laser for Heavy Ion eXperiments) at GSI Helmholtz Center for Heavy-Ion Research GmbH in Darmstadt, Germany. This thesis presents a thermoluminescence dosimetry (TLD) based method for the measurement of bremsstrahlung spectra in the energy range from 30 keV to 100 MeV. The results of the TLD measurements reinforced the observed tendency towards the strong increase of the mean electron energy and number of super-ponderomotive electrons. In the case of laser interaction with long-scale NCD-plasmas, the dose caused by the gamma-radiation measured in the direction of the laser pulse propagation showed a 1000-fold increase compared to the high contrast shots onto plane foils and doses measured perpendicular to the laser propagation direction for all used combinations of targets and laser parameters.
In this thesis I present novel characterisation method using a combination of TLD measurements and Monte Carlo FLUKA simulations applicable to laser-driven beams. The thermoluminescence detector-based spectrometry method for simultaneous detection of electrons and photons from relativistic laser-induced plasmas initially developed by Behrens et al. (Behrens et al., 2003) and further applied in experiments at PHELIX laser (Horst et al., 2015) delivered good spectral information from keV energies up to some MeV, but as it was presented in (Horst et al., 2015) this method was not really suitable to resolve the content of photon spectra above 10 MeV because of the dominant presence of electrons. Therefore, I created new evaluation method of the incident electron spectra from the readings of TLDs. For this purpose, by means of MatLab programming language an unfolding algorithm was written. It was based on a sequential enumeration of matching data series of the dose values measured by the dosimeters and calculated with of FLUKA-simulations. The significant advantage of this method is the ability to obtain the spectrum of incident electrons in the low energy range from 1 keV, which is very difficult to measure reliably using traditional electron spectrometers.
The results of the evaluation of the effective temperature of super-ponderomotive electrons retrieved from the measured TLD-doses by means of the Monte-Carlo simulations demonstrated, that application of low density polymer foam layers irradiated by the relativistic sub-ps laser pulse provided a strong increase of the electron effective temperature from 1.5 - 2 MeV in the case of the relativistic laser interaction with a metallic foil up to 13 MeV for the laser shots onto the pre-ionized foam and more than 10 times higher charge carried by relativistic electrons.
The progressive simulation method of whole electron spectra described with two -temperatures Maxwellian distribution function has been developed and the results of dose simulations were compared with the acquired experimental data. The advanced feature of this method, which distinguishes it from the results of the simulation of the photon spectrum using the interaction with the target of mono-energetic electron beams (Nilgün Demir, 2013; Nilgün Demir, 2019) or the initial electron spectrum expressed as a function of one electron temperature (Fiorini, 2012), is the ability to simulate the initial electron spectrum described by the Maxwellian distribution function with two temperatures.
The important objective of this thesis was dedicated to the study and characterisation of laser-driven photon beams. In addition to this, the positron beams were evaluated. The investigation of bremsstrahlung photons and positrons spectra from high Z targets by varying the target thickness from 10 µm to 4 mm in simulated models of the interactions of electron spectra with Maxwellian distribution functions allowed to define an optimal thickness when the fluences of photons and positrons are maximal. Furthermore based on the results of FLUKA simulations the gold material was found to be the most suitable for the future experiments as e − γ target because of its highest bremsstrahlung yield.
Additionally Monte Carlo simulations were performed applying the obtained electron beam parameters from the electron acceleration process in laser-plasma interactions simulated with particle-in-cell (PIC) code for two laser energies of 20 J and 200 J. The corresponding electron spectra were imported into a Monte Carlo code FLUKA to simulate the production process of bremsstrahlung photons and positrons in Au converter. FLUKA simulations showed the record conversion of efficiency in MeV gammas can reach 10%, which reinforces the generation of positrons. The obtained results demonstrate the advantages of long-scale plasmas of near critical density (NCD) to increase the parameters of MeV particles and photon beams generated in relativistic laser-plasma interaction. The efficiency of the laser-driven generation of MeV electrons and photons by application of low-density polymer foams is essentially enhanced.
In order to understand the origin of the elements in the universe, one must understand the nuclear reactions by which atomic nuclei are transformed. There are many different astrophysical environments that fulfill the conditions of different nucleosynthesis processes. Even though great progress has been made in recent decades in understanding the origin of the elements in the universe, some questions remain unanswered. In order to understand the processes, it is necessary to measure cross sections of the involved reactions and constrain theoretical model predictions. A variety of methods have been developed to measure nuclear reaction cross sections relevant for nuclear astrophysics. In this thesis, two different experiments and their results, both using the well-established activation method, are presented.
A measurement of the proton capture cross section on the p-nuclide 96Ru was performed at the Institute of Structure and Nuclear Astrophysics ISNAP - Notre Dame, USA. The main goal of this experiment was to compare the results with those obtained by Mei et al. in a pioneering experiment using the method of inverse kinematics at the GSI Helmholtzzentrum für Schwerionenforschung GmbH - Darmstadt, Germany. Therefore, the activations were taken out at the same center of mass energies of 9 MeV, 10 MeV and 11 MeV. Another activation was taken out at an energy of 3.2 MeV to compare the result to a measurement of Bork et al. who also used the activation method. While the results at 3.2 MeV agree quite well with those of Bork et al., the results at higher energies show significantly smaller cross sections than those measured by Mei et al.. Experimental details, the data analysis and sources of uncertainties are discussed.
The second part of this thesis describes a neutron capture cross section experiment. At the Institut für Kernphysik - Goethe Universtität Frankfurt an experimental setup allows to produce quasi maxwell-distributed neutron fields to measure maxwell-averaged cross sections (MACS) relevant for s-process nucleosynthesis. The setup was upgraded by a fast electric linear guide to transport samples from the activation to the detection site. The cyclic activation of the sample allows to increase the signal-to-noise ratio and to measure neutron captures that lead to nuclei with
half-lives on the order of seconds. In a first campaign, MACS of the reactions 51V(n,γ), 107,109Ag(n,γ) and 103Rh(n,γ) were measured. The new components of the setup aswell as the data analysis framework are described and the results of the measurements are discussed.
We study the polarization of relativistic fluids using the relativistic density operator at global and local equilibrium. In global equilibrium, a new technique to compute exact expectation values is introduced, which is used to obtain the exact polarization vector for fields of any spin. The same result has been extended to the case of massless fields. Furthermore, it is demonstrated that at local equilibrium not only the thermal vorticity but also the thermal shear contribute to the polarization vector. It is shown that assuming an isothermal local equilibrium, the new term can solve the polarization sign puzzle in heavy ion collisions.
Die vorliegende Arbeit befasst sich mit der Untersuchung der Transporteigenschaften inklusive Ladungsträgerdynamik von quasi-zweidimensionalen organischen Ladungstransfersalzen. Diese Materialien besitzen eine Schichtstruktur und weisen eine hohe Anisotropie der elektrischen Leitfähigkeit auf. Aufgrund der geringen Bandbreite und der niedrigen Ladungsträgerkonzentration gehören die Materialien zu den stark-korrelierten Elektronensystemen, wobei sich die elektronischen Eigenschaften leicht durch chemische Modifikationen oder äußere Parameter beeinflussen lassen. Die starken Korrelationen resultieren in Metall-Isolator-Übergängen, die sich beim Mott-isolierenden Zustand in einer homogenen Verteilung und beim ladungsgeordneten Zustand in einer periodischen Anordnung der lokalisierten Ladungsträger manifestieren.
Mithilfe der Fluktuationsspektroskopie, die sich mit der Analyse der zeitabhängigen Widerstandsfluktuationen befasst, konnten im Rahmen dieser Arbeit neue Erkenntnisse über die Ladungsträgerdynamik in den verschiedenen elektronischen Zuständen gewonnen werden. Die Metall-Isolator-Übergänge in den untersuchten Systemen, die auf den Molekülen BEDT-TTF (kurz: ET) bzw. BEDT-TSF (kurz: BETS) basieren, sind von der Stärke der strukturellen Dimerisierung abhängig und wurden durch die Kühlrate, eine Zugbelastung sowie durch die Ausnutzung des Feldeffekts beeinflusst.
In den Systemen κ-(BETS)₂Mn[N(CN)₂]₃, κ-(ET)₂Hg(SCN)₂Cl und κ-(ET)₂Cu[N(CN)₂]Br sind die Donormoleküle als Dimere angeordnet, sodass aufgrund der effektiv halben Bandfüllung bei genügender Korrelationsstärke häufig ein Mott-Übergang auftritt. In κ-(ET)₂Hg(SCN)₂Cl führt eine schwächere Dimerisierung jedoch zu einem Ladungsordnungsübergang, der mit elektronischer Ferroelektrizität einhergeht. Dabei wird die polare Ordnung durch eine Ladungsdisproportionierung innerhalb der Dimere verursacht. Die Widerstandsfluktuationen zeigen am ferroelektrischen Übergang einen starken Anstieg der spektralen Leistungsdichte, eine Abhängigkeit vom angelegten elektrischen Feld sowie Zeitabhängigkeiten, die auf räumliche Korrelationen der fluktuierenden Prozesse hindeuten. Diese Eigenschaften wurden ebenfalls für das System κ-(BETS)₂Mn[N(CN)₂]₃ beobachtet. Hierbei wurden mithilfe der dielektrischen Spektroskopie ebenfalls Hinweise auf Ferroelektrizität gefunden, während durch die Analyse der stromabhängigen Widerstandsfluktuationen die Größe der polaren Regionen abgeschätzt werden konnte. Das System κ-(ET)₂Cu[N(CN)₂]Br, das in einer Feldeffekttransistor-Struktur vorliegt, erlaubt neben der Untersuchung des Bandbreiten-getriebenen Mott-Übergangs durch die Zugbelastung eines Substrats auch die Beeinflussung der elektronischen Eigenschaften durch die Änderung der Bandfüllung mittels elektrostatischer Dotierung. Hierbei wurden starke Abhängigkeiten des Widerstands von der Gatespannung beobachtet und Ähnlichkeiten der Ladungsträgerdynamik zu herkömmlichen Volumenproben gefunden.
Bei den Systemen θ-(ET)₂MM'(SCN)₄ mit MM'=CsCo, RbZn, TlZn tritt ein Ladungsordnungsübergang auf, der eine starke Abhängigkeit von der Kühlrate zeigt. Durch schnelles Abkühlen lässt sich der Phasenübergang erster Ordnung kinetisch vermeiden, wodurch ein Ladungsglaszustand realisiert wird. Dieser metastabile Zustand zeigt neuartige physikalische Eigenschaften mit Ähnlichkeiten zu herkömmlichen Gläsern und wurde als Folge der geometrischen Frustration der Ladung auf einem Dreiecksgitter diskutiert. Im Rahmen dieser Arbeit konnte die Ladungsträgerdynamik in den verschiedenen Ladungszuständen von unterschiedlich frustrierten Systemen verglichen werden. Zur Realisierung sehr schneller Abkühlraten wurde dafür eine Heizpulsmethode verwendet und weiterentwickelt. Der Ladungsglaszustand zeigte dabei für verschiedene Systeme ein deutlich niedrigeres Rauschniveau als der ladungsgeordnete Zustand. In Kombination mit Messungen der thermischen Ausdehnung und kühlratenabhängiger Transportmessungen wurde in den Systemen mit der stärksten Frustration die Existenz eines strukturellen Glasübergangs nachgewiesen, der von einer starken Verlangsamung der Ladungsträgerdynamik begleitet wird. Diese Erkenntnisse werfen ein neues Licht auf die bisherige rein elektronische Interpretation des Ladungsglaszustands und heben den Einfluss der strukturellen Freiheitsgrade hervor.
This work ties in with the investigation of the intermediate valent states and valence fluctuations in certain europium based intermetallic systems. Valence fluctuations are a property of the electronic system of a compound that is possibly accompanied by structural effects, which, in some cases, are quite noticable. By assuming how the changes in the electronic system and in the crystal lattice are connected, valence _uctuations of europium are believed to be a possible probe for the theory of quantum critical elasticity, which is investigated on by the SFB TRR 288 (Frankfurt, Mainz, Karlsruhe, Bochum, Dresden).
Here, the proceedings in growing single crystals of di_erent compounds related to this _eld of research are reported. This includes the ThCr2Si2 (122) type compounds EuPd2Si2 as well as the doping series EuPd2(Si1-xGex)2, the Europium based ternary Phosphides EuFe2P2, EuCo2P2, EuNi2P2 and EuRu2P2, and attempts to grow compounds of a derived 1144 structure by ordered substitution of half the Europium, EuKRu4P4.
The largest part of this work focusses on the EuPd2Si2 system, which exhibits intermediate valent europium and a temperature dependent transition between two di_erent intermediate valent states of europium. Crystals of this system were grown using the Czochralski method with a levitating melt and an europium excess flux after a two step prereaction process. Also, explorations of a PdSi-rich flux and external flux methods are reported. Ten Czochralski grown experiments, in six generations iteratevely seeded by the previous generation, were prepared.
Thermodynamical and structural analyses of the crystals located the transition between the di_erent intermediate valent states of europium between 140K and 165 K, transitioning from a high temperature Eu2.3+ state to a low temperature Eu2.7+ state, and classified it as a second order transition. To this transition a lattice anomaly of the a-parameter collapsing about 2% is connected, while the c-parameter remains largely unaffected. Large differences between individual samples can be explained by combining thermodynamical and structural analyses with compositional analysis, revealing the valence transition temperature as strongly dependent on the sample composition and Pd-Si site interchanges.
Searching to change the character of the valence transition to first order, silicon was substituted by germanium to introduce negative pressure. Germanium substituted samples of EuPd2(Si1-xGex)2 were grown using the Czochralski method with the optimized parameters from the growth experiments for the undoped compound. Samples were prepared with a nominal substitution of x = 0.05, x = 0.10, x = 0.15, x = 0.20 (twice) and x = 0.30. For the EuPd2(Si1-xGex)2 system, a phase diagram for the europium valence states is derived from chemical and thermodynamical characterizations.
n ternary europium phosphides EuT2P2, the position of the compounds in the generalized phase diagram and the question of long range magnetic order or valence transition appear connected to an isostructural transition of the tetragonal crystal structure, drastically decreasing the length of the c-parameter while establishing covalent bonds between phosphorus atoms of different interlayers of the structure, the so called ‚collapse‘. While EuFe2P2, EuT2P2 and EuCo2P2 display both long range magnetic order and a non-collapsed crystal structure, EuNi2P2 shows both a valence transition between two intermediate valent states at a characteristic temperature of 36K - accompanied by a small lattice anomaly of the a-parameter shrinking about 0.2% - and a collapsed crystal structure. Samples of EuFe2P2, EuCo2P2 and EuNi2P2 were grown in tin flux and using solid-solid sintering approaches.
Single crystals of EuFe2P2, EuCo2P2 and EuRu2P2 were investigated at ESRF in Grenoble with single crystal X-ray di_ractometry on a pressure range up to 15GPa and at temperatures down to 15K to investigate the nature of the structural transitions in the compounds. While in EuCo2P2 the structural transition occurs as a transition of first order at all temperatures (e.g. at 2GPa for 15 K), in EuFe2P2 and EuRu2P2 the structural collapse evolves over a broad pressure range up to 8GPa and as a transition of second order troughout the temperature ranges, albeit seeming to sharpen at lower temperatures. From the crystallographic data, elastic constants of the compounds could be derived, revealing EuFe2P2 and EuRu2P2 as unexpectedly elastic materials.
In order to probe the structural collapse at more accessible pressures, crystals with a sturcture derived from the 122 structure, but with ordered 50% substitution of europium and hence altering the symmetry from I4/mmm to P4/mmm in a 1144 structure, were exploratively pursued. Different experiments to obtain EuAT4P4 (with A = K, Rb, Cs and T = Fe, Ru) from binary or ternary prereactants or directly from the elements remained largely unsuccessful.
High-resolution, compactness, scalability, efficiency – these are the critical requirements which imaging radar systems have to fulfil in applications such as environmental monitoring, cloud mapping, body sensing or autonomous driving. This thesis presents a modular millimetre-wave frequency modulated continuous-wave (FMCW) radar front-end solution intended for such applications. High-resolution is achieved by enlarging the operating frequency band of the radar system. This can be realized at millimetre-wave frequencies due to the large spectrum availability. Furthermore, the size of components decreasing with increasing frequency makes millimetre-wave systems a good candidate for compactness. However, the full integration of radar front-ends is a challenge at millimetre-wave frequencies due to poor signal integrity and spectral purity, which are essential for imaging applications. The proposed radar uses an alternative technique and tackles this limitation by featuring highly-integrable architectures, specifically the Hartley architecture for signal conversion and enhanced push-pull amplifier for harmonic suppression. The resolution of imaging radars can be further improved by increasing the number of transmitters and receivers. This has spurred the investigation of spectrum, time and energy-efficient multiplexing techniques for multi-input multi-output (MIMO) radar systems. The FMCW radar architecture proposed in this thesis is based on code-division technique using intra-pulse, also called intra-chirp modulation. This advanced scalable and non-complex solution, made possible by the latest achievements on direct digital synthesis for signal generation, guarantees signal integrity and compact size implementation. The proposed architecture is investigated by a thorough system analysis. A transmitter module and a receiver module for a 35 GHz imaging radar prototype are designed, fabricated and fully characterized to validate the feasibility of our novel approach for high-resolution highly-integrated MIMO front-ends.
Simulations of conformational changes and enzyme-substrate interactions in protein drug targets
(2022)
Finding new drugs is a difficult, time-consuming, and costly challenge, with only a small success rate along the drug discovery pipeline of far less than 10%. The high failure rate of drug discovery projects motivates the integration of computational tools throughout the whole drug discovery pipeline, from target identification to clinical trials. Target identification is the first step in the process. A biological target, e.g., a protein that plays a role in disease, is identified and its molecular mechanism in the disease is studied. Further, a potential binding site on the target, where therapeutic molecules can bind and modulate the target’s activity, needs to be characterized. Computational tools can contribute to improving the initial molecular target elucidation and assessment.
In this thesis, I use computational, physics-based approaches to characterize binding sites of drug targets and to decipher enzyme-substrate interactions, which play a role in disease mechanisms. Molecular dynamics (MD) simulations were applied to study the dynamics of molecules in solution at high temporal and spatial resolution. The method generates time-resolved trajectories of the particles in a system of interest by integrating Newton’s equations of motion numerically, starting from a set of coordinates and velocities. In MD simulations, all atoms of a chosen system, including solvent, are represented explicitly. Atomistic simulations are especially well-suited to study detailed interactions that depend on intermolecular interactions, such as hydration effects, hydrogen bonding, hydrophobic interactions, or subtle chemical differences. System properties are inferred from the trajectories, provided that the force fields, describing the interactions between the particles in the system, have a high accuracy. The bonded and non-bonded interactions are parametrized on experimental and quantum chemical data. The purpose of MD simulations can be to gain insight into the behavior of complex biological systems at molecular level, which often cannot be observed in experiments at the same resolution. With recent advances in computer hardware and simulation software, molecular systems of increasing size and simulation length can be investigated.
In the first part of the thesis, I investigated the conformational ensemble of various protein drug targets. Proteins are dynamic biomacromolecules that can have diverse and nearly isoenergetic conformational states. Ligand binding can shift the equilibrium of this conformational ensemble and can uncover binding sites, called cryptic sites. Cryptic sites only emerge upon small molecule binding and are often flat and featureless, and thus not easily recognized in crystal structures without bound ligands. If new binding sites including cryptic sites are detected, they can potentially be exploited for binding to ligands and enable a druggable target. Druggability is the ability of a protein to bind small, drug-like molecules, which is the basis for rational drug design. In this thesis, I used state-of-the-art physics-based, computational approaches to investigate the conformational ensembles of binding sites. In all studied systems, it is known from experiment that a specific group of ligands can induce conformational changes. The aim is to sample the conformational space made accessible upon ligand binding, yet without using the specific ligand structures or details about their interactions. We are interested in sampling the
pocket conformational states and identifying the respective pocket opening mechanism. For some cases, I additionally assessed whether the observed flexibility is a feature of the protein family, or specific to the protein under consideration.
The first studied system is factor VIIa (FVIIa). FVIIa is an essential part of the coagulation cascade and hence a potential drug target for thrombotic diseases. In addition, I investigated various other trypsin-like serine proteases from the same protein family. The binding pocket of trypsin-like serine proteases is called S1 pocket. An X-ray crystal structure solved by our collaborators reveals that a b-sheet structure in the S1 pocket is distorted by a bound ligand. I resolved the conformational change with MD simulations, starting from the unbound protein structure solvated in water and ions. I observed multiple spontaneous transition events. In 7 out of 22 simulations with the b-sheet as starting structure, the S1 pocket eventually rearranged into a distorted loop structure. These transitions occurred spontaneously and were mediated by water molecules probing the backbone hydrogen bonds. The conformational change studied here controls the onset of substrate binding and catalysis. Furthermore, I used metadynamics simulation, an enhanced-sampling method, to estimate the free energy barrier of this conformational change..
This thesis has two main parts.
The first part is based on our publication [1], where we use perturbation theory to calculate decay rates of magnons in the Kitaev-Heisenberg-Γ (KHΓ) model. This model describes the magnetic properties of the material α-RuCl 3 , which is a candidate for a Kitaev spin liquid. Our motivation is to validate a previous calculation from Ref. [2]. In this thesis, we map out the classical phase diagram of the KHΓ model. We use the Holstein-Primakoff
transformation and the 1/S expansion to describe the low temperature dynamics of the Kitaev-Heisenberg-Γ model in the experimentally relevant zigzag phase by spin waves. By parametrizing the spin waves in terms of hermitian fields, we find a special parameter region within the KHΓ model where the analytical expressions simplify. This enables us to construct the Bogoliubov transformation analytically. For a representative point in the special parameter region, we use these results to numerically calculate the magnon damping, which is to leading order caused by the decay of single magnons into two. We also calculate the dynamical structure factor of the magnons.
The second part of this thesis is based on our publication [3], where we use the functional renormalization group to analyze a discontinuous quantum phase transition towards a non-Fermi liquid phase in the Sachdev-Ye-Kitaev (SYK) model. In this thesis, we perform a disorder average over the random interactions in the SYK model. We argue that in the thermodynamic limit, the average renormalization group (RG) flow of the SYK model is identical to the RG flow of an effective disorder averaged model. Using the functional RG, we find a fixed point describing the discontinuous phase transition to the non-Fermi liquid phase at zero temperature. Surprisingly, we find a finite anomalous dimension of the fermions, which indicates critical fluctuations and is unusual for a discontinuous transition. We also determine the RG flow at zero temperature, and relate it to the phase diagram known from the literature.