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Professor Walter Greiner, our mentor, colleague, and friend, passed away in the age of eighty. During his lifetime, the search for elements beyond uranium started and elements up to the so far heaviest one with atomic number 118 were discovered. In this talk I will present a short history from early searches for ‘trans-uraniums’ up to the production and safe identification of shell-stabilized ‘Super-Heavy Nuclei’ (SHN). The nuclear shell model reveals that these nuclei should be located in a region with closed shells for the protons at Z = 114, 120 or 126 and for the neutrons at N = 184. The outstanding aim of experimental investigations is the exploration of this region of spherical SHN. Systematic studies of heavy ion reactions for the synthesis of SHN revealed production cross-sections which reached values down to one picobarn and even below for the heaviest species. The systematics of measured cross-sections can be understood only on the basis of relatively high fission barriers as predicted for nuclei in and around the island of SHN. A key role in answering some of the open questions plays the synthesis of isotopes of element 120. Attempts aiming for synthesizing this element at the velocity filter SHIP will be reported.
We study tetraquark resonances with lattice QCD potentials computed for two static quarks and two dynamical quarks, the Born-Oppenheimer approximation and the emergent wave method of scattering theory. As a proof of concept we focus on systems with isospin I = 0, but consider different relative angular momenta l of the heavy b quarks. We compute the phase shifts and search for S and T matrix poles in the second Riemann sheet. We predict a new tetraquark resonance for l = 1, decaying into two B mesons, with quantum numbers I(JP) = 0(1−), mass MeV and decay width MeV.
Die vorliegende Dissertation befasst sich mit der Entwicklung und Erforschung eines konzeptionell neuartigen Injektionssystems zum Transport von Ionenstrahlen in toroidale Magnetfeldstrukturen. Die Forschungsarbeit ist dabei Teil des Figure-8 Speicherringprojekts (F8SR) des IAP, bei welchem es um die Erforschung der Physik und die Entwicklung eines niederenergetischen, supraleitenden, magnetostatischen Figure-8 Hochstromspeicherrings geht. Dieser neuartige Speicherring ermöglicht aufgrund des Einsatzes von fokussierenden solenoidalen und toroidalen Magnetfeldern das Speichern von Strahlströmen von bis zu einigen Ampere. Diese Arbeit baut auf früheren Forschungsarbeiten zu diesem Themenfeld auf, in welchen die Grundlagen und Ausgangsparameter für die experimentelle Untersuchung der Injektion gelegt und mit dem Aufbau des Injektionsexperiments begonnen wurde.
In dieser Dissertation wird den Fragen nachgegangen, ob ein magnetisches Konzept des Injektionssystems mittels eines „Scaled-Down“-Experiments experimentell umsetzbar ist und ob mit diesem die Injektion von Ionenstrahlen in toroidale Magnetfeldstrukturen realisiert werden kann. Ziel ist es dabei, ein Injektionssystem aufzubauen, durch welches sowohl ein seitlich injizierter Injektionsstrahl, welcher den in den Speicherring zu injizierenden Strahl darstellt, als auch ein gleichzeitig durch die toroidalen Magnetfelder driftender Ringstrahl, welcher den im Speicherring zirkulierenden Strahl darstellt, ohne Verluste transportiert werden können. Das Injektionssystem besteht dabei aus drei normalleitenden Magneten, wobei es sich um zwei baugleiche 30 Grad Toroide sowie einen Solenoid handelt. Die Toroide bilden den Transportkanal für den Ringstrahl, während der Injektionssolenoid senkrecht zwischen den beiden Toroiden endet und den Injektionskanal für den Injektionsstrahl darstellt.
Zunächst wurde das Injektionssystem mittels Strahltransportsimulationen untersucht und aufbauend auf den Ergebnissen die benötigen Vakuumkomponenten sowie der Injektionsmagnet ausgelegt, entwickelt und umgesetzt. Anschließend wurde mit dem fertigstellten Injektionsexperiment der Transport von zwei Ionenstrahlen durch das Injektionssystem experimentell erforscht. Dabei wurden die Strahlpfade mit einem in Entwicklung befindlichen Kameradetektorsystem aus verschiedenen Perspektiven aufgenommen und das Strahlverhalten in Abhängigkeit von unterschiedlichen Parametern phänomenologisch analysiert und diskutiert, mit den Ergebnissen der Simulationen verglichen sowie theoretisch bzgl. der RxB Drift und eines Gedankenmodells eingeordnet. Die technische Umsetzung, Inbetriebnahme und Durchführung verschiedener Vorabexperimente bzgl. weiterer Komponenten des Injektionsexperiments (bspw. Ionenquellen und Filterkanäle) ist ebenfalls Bestandteil dieser Arbeit.
Bei den experimentellen Untersuchungen mit Wasserstoff- und Heliumionenstrahlen konnte beobachtet werden, wie der Injektionsstrahl in den zweiten Toroid driftet und somit erfolgreich injiziert wird. Des Weiteren wurde eine Heliummessung durchgeführt, bei der sowohl der Injektionsstrahl als auch der Ringstrahl erfolgreich durch das Injektionssystem transportiert werden konnten. Auch die Auswirkungen des Injektionsmagneten auf den Ringstrahl konnten experimentell untersucht werden. Die verschiedenen Messungen wurden mittels des Gedankenmodells diskutiert und mit den Ergebnissen der Simulationen sowie untereinander verglichen.
Das abschließende Ergebnis dieser Arbeit ist, dass durch den Einsatz von solenoidalen und toroidalen Magnetfeldern der Injektionsstrahl vom Injektionsmagneten in den zweiten Toroid transportiert und dieser somit in die gekoppelte magnetische Konfiguration der Toroide eingelenkt werden kann. Der gleichzeitige verlustfreie Transport eines Ringstahls durch das Injektionssystem konnte dabei ebenfalls realisiert werden. Des Weiteren stimmen die Ergebnisse der Simulationen und Experimente sowie die theoretischen Überlegungen überein.
Das neuartige Injektionskonzept, welches als Schlüsselkomponente für die Umsetzung des Figure-8 Hochstromspeicherrings benötigt wird, wurde somit mittels Theorie, Simulation und Experiment überprüft und die Funktionalität bestätigt.
Zukünftige Forschungsfragen für welche der Figure-8 Hochstromspeicherring verwendet werden könnte, bspw. aus den Bereichen der experimentellen Astrophysik oder Fusionsforschung, wurden abschließend diskutiert.
Defossiliation of the energy system is crucial in the face of the impending risks of climate change. Electricity generation by burning fossil fuels is being displaced by renewable energy sources like hydro, wind and solar, driven by support schemes and falling costs from technological advances as well as manufacturing scale effects. The unavoidable shift from flexibly dispatchable generation to weather-dependent spatio-temporally varying generators transforms the generation and distribution of electricity into highly interdependent complex systems in multiple dimensions and disciplines:
In time, different scales, stretching from intra-day, diurnal, synoptic to seasonal oscillations of the weather interact with years and decades of planning and construction of capacity. In space, long-range correlations and local variations of weather systems as well as local bottlenecks in transmission networks affect solutions. The investment decisions about technological mix and spatial distribution of capacity follow economic principles, within restrictions which adapt in social feedback loops to public opinion and lobbyist influences.
In this work, a family of self-consistent models is developed which map physical steady-state operation, capacity investments and exogeneous restrictions of a European electricity system, in higher simultaneous spatial and temporal detail as well as scope than has previously been computationally tractable. Increasing the spatial detail of the renewable resources and co-optimizing the expansion of only a few transmission lines, reveals solutions to serve the European electricity demand at about today’s electricity cost with only 5% of its carbon-dioxide emissions; and importantly their electricity mix differs from the findings at low spatial resolution.
As important intermediate steps,
• new algorithms for the convex optimization of electricity system infrastructure are derived from graph-theoretic decompositions of network flows. Only these enable the investigation of model detail beyond previous computational limitations.
• a comprehensive European electricity network model down to individual substations at the transmission voltage levels is built by combining and completing data from freely available sources.
• a network reduction technique is developed to approximate the detailed model at a sequence of spatial resolutions to investigate the role of spatial scale, and identify a level of spatial resolution which captures all relevant detail, but is still computationally tractable.
• a method to trace the flow of power through the network, which is related to a vector diffusion process on a directed flow graph embedded in a network, is used to analyse the resulting technology mix and its interactions with the power network
The open-source nature of the model and restriction to freely available data encourages an accessible and transparent discussion about the future European electricity system, primarily based on renewable wind and solar resources.
We present a 360∘ (i.e., 4π steradian) general-relativistic ray-tracing and radiative transfer calculations of accreting supermassive black holes. We perform state-of-the-art three-dimensional general-relativistic magnetohydrodynamical simulations using the BHAC code, subsequently post-processing this data with the radiative transfer code RAPTOR. All relativistic and general-relativistic effects, such as Doppler boosting and gravitational redshift, as well as geometrical effects due to the local gravitational field and the observer’s changing position and state of motion, are therefore calculated self-consistently. Synthetic images at four astronomically-relevant observing frequencies are generated from the perspective of an observer with a full 360∘ view inside the accretion flow, who is advected with the flow as it evolves. As an example we calculated images based on recent best-fit models of observations of Sagittarius A*. These images are combined to generate a complete 360∘ Virtual Reality movie of the surrounding environment of the black hole and its event horizon. Our approach also enables the calculation of the local luminosity received at a given fluid element in the accretion flow, providing important applications in, e.g., radiation feedback calculations onto black hole accretion flows. In addition to scientific applications, the 360∘ Virtual Reality movies we present also represent a new medium through which to interactively communicate black hole physics to a wider audience, serving as a powerful educational tool.
In the course of this thesis we discuss a certain kind of supersolid, the lattice-supersolid, which can be realized using quantum gases in an optical lattice trap. The lattice-supersolid, which simultaneously possesses off-diagonal and diagonal long-range order in its density matrix and also breaks the discrete translational symmetry of an underlying lattice, is induced by self-ordering of the gas due to strong long-range van der Waals interactions. In the considered scenario, the interactions are facilitated by the excitation of atomic Rydberg states, which exhibit enhanced van der Waals forces.
In the first part of this thesis (chapters 1-3), we review the relevant basics of quantum gases, Rydberg physics and introduce the extended Bose-Hubbard model. We start with the relevant methods and devices of the vast toolbox available in common quantum gas experiments, as well as consider the main concepts behind superfluidity and supersolidity. This is followed by an introduction of some basic concepts of Rydberg atoms in quantum many-body systems, with a focus on the facilitation of long-range interactions and the implementation in a theoretical model. Thereafter a brief introduction is given, on the realization of the Bose-Hubbard model in optical lattice systems and its extension to include Rydberg states, which concludes the introductory part of this thesis.
In the following part (chapters 4-6), we introduce the theoretical tools used to derive the results presented in the final part. First, an introduction to a real-space extension of bosonic dynamical mean-field theory (RB-DMFT) for bosonic systems with long-range interactions in the Hartree approximation is given. This method is based on the non-perturbative self-consistent evaluation of the lattice Green’s function, which also incorporates the effect of nearest neighbor correlations due to the non-condensed particles. Then we focus on a quasiparticle expansion of the Bose-Hubbard model, which has its foundation in linearized fluctuations of a static mean-field ground-state, allowing for the prediction of a vast range of experimentally relevant observables. Lastly, we introduce an efficient truncation scheme for the local bosonic Fock-basis, which allows for the simulation of phases with high condensate density at a vastly reduced computational effort.
In the final part (chapters 7 and 8), we discuss the application of both methods to itinerant bosonic gases in two-dimensional optical lattices, in order to predict the equilibrium ground-state phases, as well as the signatures of supersolidity and its formation in spectral functions and the dynamic and static structure factor. Specifically, we focus on two limiting cases. Firstly, we consider a two-component gas, as realized by two hyperfine ground states, for example, of rubidium-87, where one component is off-resonantly excited to a Rydberg state, which generates a soft-core shaped interaction potential. Secondly, we discuss the opposing limit, using near-resonant excitations
of Rydberg states, where the interacting component now directly corresponds to the Rydberg state, which interacts via a van der Waals potential. In both cases we discuss the rich variety of supersolid phases, which are found for a wide range of parameters. We also discuss how some of these phases can be realized in experiment.
In the subsequent appendices (A to D) we discuss some methodological details. Most notably, we consider the possible Fock-extension of the Hartree approximation (appendix A), introduced in the RB-DMFT treatment of the extended Bose-Hubbard model.
This thesis presents the first measurement of the proton capture reaction on the isotope 124Xe performed in inverse kinematics. The experiment was carried out in June 2016 at the Experimental Storage Ring (ESR) at the GSI Helmholtz Centre for Heavy Ion Research in Darmstadt, Germany.
124Xe is one of about 35 p-nuclei that cannot be produced via neutron-induced nucleo- synthesis as the vast majority of heavy elements. Its production and destruction provide important information about the nucleosynthesis of the p-nuclei. Measuring the 124Xe(p,g)125Cs reaction also gives strong constraints for its reverse 125Cs(g,p)124Xe reaction.
Fully stripped 124Xe ions repeatedly passed a H2 gas jet target at five different energies between 5.5 MeV/u and 8 MeV/u. An electron cooler compensated for the energy loss in the target and reduced the beam momentum spread. The reaction product 125Cs55+ has a smaller magnetic rigidity than 124Xe54+. Therefore 125Cs55+ was deflected towards smaller radii in the first dipole after the target area and thereby separated from 124Xe54+. It was detected with a position-sensitive Double-Sided Silicon Strip Detector (DSSSD). The novelty of this experiment was the installation of the DSSSD inside the ultra-high vacuum of the storage ring using a newly designed manipulator.
Three High-Purity Germanium X-ray detectors were used to measure the X-rays following the Radiative Electron Capture (REC) events into 124Xe53+. The REC cross sections are well-known and were used to determine the luminosity.
The 124Xe(p,g)125Cs cross sections at ion beam energies between 5.5 MeV/u and 8 MeV/u were determined relatively to the K-REC cross sections and finally compared to the theoretically predicted cross sections. While theoretical predictions of the TENDL database are lower than the measured ones by a factor of up to seven, the NON-SMOKER data are higher by a factor of up to two, except of the cross section at 7 MeV/u, where NON-SMOKER data are slightly lower than the experimental value.
For the first time, a proton capture cross section could be measured in inverse kinematics close to the astrophysically relevant Gamow window. This allows the direct determination of the (p,g) cross section of isotopes with half-lives down to several minutes, which is not possible with any other technique.
In this thesis we work on the theoretical description of relativistic heavy-ion collisions, focussing on electromagnetic probes. We present mainly four topics: electric conductivity and diffusion properties of the hot plasma and hadronic matter, response of the quark-gluon plasma to external magnetic fields, direct photon production in the quark-gluon plasma and a study about initial and final state effects in small systems. The latter topic aims, i.a., at a better understanding of the initial state, which is crucial for electromagnetic probes. In all research areas we make use of the Boltzmann transport equation, whereby the presented methods provide analytical and numerical solutions. We pay particular attention to the construction of complete leading order photon production processes in numerical transport simulations of the quark-gluon plasma.
To begin with, our findings are the complete conserved charge diffusion matrix and electric conductivity. Those properties are important ingredients, e.g., for future simulations of baryon rich collisions. Next, we find that the influence of external magnetic fields to the QGP dynamics is not quantifiable in observables.
We present results for a variety of direct photon observables and we can partly explain experimental data. We emphasize the importance of the chemical composition and non-equilibrium nature of the medium to the direct photon puzzle. Lastly, we observe the interesting dynamic behavior of azimuthal correlations in small systems and identify signatures of the initial state in final observables. This will also be of interest for more precise simulations of electromagnetic probes and allows for various future studies.
Most of superconductors in a magnetic field are penetrated by a lattice of quantized flux vortices. In the presence of a transport current causing the vortices to cross sample edges, emission of electromagnetic waves is expected due to the continuity of tangential components of the fields at the surface. Yet, such a radiation has not been observed so far due to low radiated power levels and lacking coherence in the vortex motion. Here, we clearly evidence the emission of electromagnetic waves from vortices crossing the layers of a superconductor/insulator Mo/Si superlattice. The emission spectra consist of narrow harmonically related peaks which can be finely tuned in the GHz range by the dc bias current and, coarsely, by the in-plane magnetic field value. Our findings show that superconductor/insulator superlattices can act as dc-tunable microwave generators bridging the frequency gap between conventional radiofrequency oscillators and (sub-)terahertz generators relying upon the Josephson effect.
Die vorliegende Arbeit präsentiert die wissenschaftlichen Erkenntnisse, welche im Rahmen dreier verschiedener Messreihen gewonnen wurden. Kernthema ist in allen Fällen die Ionisation von molekularem Wasserstoff mit Photonen.
Im Rahmen der Messung sollte eine 2014 veröffentlichte Vorhersage der theoretischen Physiker Vladislav V. Serov und Anatoli S. Kheifets im Experiment überprüft werden. Ihren Berechnungen zufolge kann ein sich langsam vom Wasserstoff Molekülion entfernendes Photoelektron durch sein elektrisches Feld das Mutterion polarisieren und dafür sorgen, dass beim anschließenden Aufbruch in ein Proton und ein Wasserstoffatom eine asymmetrische Emissionswinkelverteilung zu beobachten ist [SK14]. Diese Vorhersage konnte mit den Ergebnissen der hier vorgestellten Messung zweifelsfrei untermauert werden. Für drei verschiedene Photonenenergien, welche im relevanten Reaktionskanal Photoelektronenenergien von 1, 2 und 3 eV entsprechen, wurden die prognostizierten Symmetrien in den Messdaten herauspräpariert. Es zeigte sich, dass diese sowohl in qualitativer wie auch in quantitativer Hinsicht gut bis sehr gut mit den Vorhersagen übereinstimmen.
Im zweiten Teil dieser Arbeit wurde erneut die Dissoziationsreaktion, allerdings bei deutlich höheren Photonenenergien, untersucht. Ziel war es, den in Zusammenarbeit mit den Physikern um Fernando Martin gelungenen theoretischen Nachweis der Möglichkeit einer direkten Abbildung von elektronischen Wellenfunktionen auch im Experiment zu vollziehen. Der überwiegende Teil aller Veröffentlichungen im Vorfeld dieser Messung fokussierte sich bei den Untersuchungen der Wellenfunktion entweder auf die rein elektronischen Korrelationen - so zum Beispiel in Experimenten zur Ein-Photon-Doppelionisation, wo Korrelationen zwischen beiden beteiligten Elektronen den Prozess überhaupt erst möglich machen - oder aber auf den Einfluss, welchen das Molekülpotential auf das emittierte Elektron ausübt. Die wenigen Arbeiten, die sich bis heute an einer unmittelbaren Abbildung elektronischer Wellenfunktionen versuchten, gingen meist den im Vergleich zu dieser Arbeit umgekehrten Weg: Man untersuchte hier das Licht höherer Harmonischer, wie sie bei der lasergetriebenen Ionisation und anschließenden Rekombination eines Photoelektrons mit seinem Mutterion entstehen.
In dieser Arbeit wurde ein Ansatz präsentiert, der zwei überaus gängige und verbreitete Messtechniken geschickt kombiniert - Während das Photoelektron direkt nachgewiesen und seine wesentlichen Eigenschaften abgefragt werden, kann der quantenmechanische Zustand des zweiten, gebunden verbleibenden Elektrons über einen koinzident dazu geführten Nachweis des ionischen Reaktionsfragments bestimmt werden. Dieser Vorgang stützt sich wesentlich auf Berechnungen der Gruppe um Fernando Martín, welche eine Quantifizierung der Beiträge einzelner Zustande zum gesamten Wechselwirkungsquerschnitt dieser Reaktion erlauben. Diese unterscheiden sich je nach Energie der Fragmente signifikant, so dass über eine Selektion des untersuchten KER-Intervalls Kenntnis vom elektronischen Zustand des H2 +-Ions nach der Photoemission erlangt werden kann. Die experimentellen Daten unterstützen die Theorie von Martin et al. nicht nur mit verblüffend guter Übereinstimmung, die gemessenen Emissionswinkelverteilungen stehen darüber hinaus auch in sehr gutem Einklang mit ihren theoretisch berechneten Gegenstücken. Die Ergebnisse wurden zwischenzeitlich in der renommierten Fachzeitschrift Nature Communications veröffentlicht [WBM+17].
Die dritte Messreihe innerhalb dieser Arbeit beschäftigt sich mit der Photodoppelionisation von Wasserstoff. Im Rahmen des selben Experiments wie die weiter vorn beschriebene Dissoziationsmessung bei 400 eV Photonenenergie aufgenommen, belegen die Ergebnisse auf wunderbar anschauliche Art und Weise, dass die Natur in unserer Umgebung voller Prozesse ist, die ursprünglich als rein quantenmechanische Laborkonstrukte angesehen wurden. Es konnte zweifelsfrei gezeigt werden, dass die beiden Elektronen, die bei der Photodoppelionisation freigesetzt werden, als ein Quasiteilchen aufgefasst werden können. Sie befinden sich in einem verschränkten Zweiteilchenzustand, und nur eine koinzidente Messung beider Elektronen vermag es, Interferenzeffekte in ihren Impulsverteilungen sichtbar zu machen - betrachtet man beide hingegen individuell, so treten keinerlei derartige Phänomene auf. Es gelang dabei zudem, eine beispielhafte Übereinstimmung zwischen den gemessenen Daten und einer theoretischen Berechnung der Kollegen um Fernando Martín zu erreichen.
Fabrication of three-dimensional (3D) nanoarchitectures by focused electron beam induced deposition (FEBID) has matured to a level that highly complex and functional deposits are becoming available for nanomagnetics and plasmonics. However, the generation of suitable pattern files that control the electron beam’s movement, and thereby reliably map the desired target 3D structure from a purely geometrical description to a shape-conforming 3D deposit, is nontrivial. To address this issue we developed several writing strategies and associated algorithms implemented in C++. Our pattern file generator handles different proximity effects and corrects for height-dependent precursor coverage. Several examples of successful 3D nanoarchitectures using different precursors are presented that validate the effectiveness of the implementation.
The ATP-binding cassette transporter TAPL translocates polypeptides from the cytosol into the lysosomal lumen. TAPL can be divided into two functional units: coreTAPL, active in ATP-dependent peptide translocation, and the N-terminal membrane spanning domain, TMD0, responsible for cellular localization and interaction with the lysosomal associated membrane proteins LAMP-1 and LAMP-2. Although the structure and function of ABC transporters were intensively analyzed in the past, the knowledge about accessory membrane embedded domains is limited. Therefore, we expressed the TMD0 of TAPL via a cell-free expression system and confirmed its correct folding by NMR and interaction studies. In cell as well as cell-free expressed TMD0 forms oligomers, which were assigned as dimers by PELDOR spectroscopy and static light scattering. By NMR spectroscopy of uniformly and selectively isotope labeled TMD0 we performed a complete backbone and partial side chain assignment. Accordingly, TMD0 has a four transmembrane helix topology with a short helical segment in a lysosomal loop. The topology of TMD0 was confirmed by paramagnetic relaxation enhancement with paramagnetic stearic acid as well as by nuclear Overhauser effects with c6-DHPC and cross-peaks with water.
Self-organized robots may develop attracting states within the sensorimotor loop, that is within the phase space of neural activity, body and environmental variables. Fixpoints, limit cycles and chaotic attractors correspond in this setting to a non-moving robot, to directed, and to irregular locomotion respectively. Short higher-order control commands may hence be used to kick the system from one self-organized attractor robustly into the basin of attraction of a different attractor, a concept termed here as kick control. The individual sensorimotor states serve in this context as highly compliant motor primitives. We study different implementations of kick control for the case of simulated and real-world wheeled robots, for which the dynamics of the distinct wheels is generated independently by local feedback loops. The feedback loops are mediated by rate-encoding neurons disposing exclusively of propriosensoric inputs in terms of projections of the actual rotational angle of the wheel. The changes of the neural activity are then transmitted into a rotational motion by a simulated transmission rod akin to the transmission rods used for steam locomotives. We find that the self-organized attractor landscape may be morphed both by higher-level control signals, in the spirit of kick control, and by interacting with the environment. Bumping against a wall destroys the limit cycle corresponding to forward motion, with the consequence that the dynamical variables are then attracted in phase space by the limit cycle corresponding to backward moving. The robot, which does not dispose of any distance or contact sensors, hence reverses direction autonomously.
Das Standardmodell der Elementarteilchenphysik beschreibt nach aktuellem Kenntnisstand die Entstehung, den Aufbau und das Verhalten der Materie in unserem Universum am erfolgreichsten. Dennoch gibt es einige Phänomene, die sich nicht in dessen Rahmen beschreiben lassen, wie z. B. die Existenz von dunkler Materie und Energie, nicht-verschwindende Neutrinomassen oder die Baryonenasymmetrie. Speziell im Hinblick auf die starke Wechselwirkung, welche im Standardmodell durch die Quantenchromodynamik (QCD) beschrieben wird, gibt es noch immer viele offene Fragen.
Eine Umgebung, in der man die QCD experimentell ergründen kann, bieten vor allem Schwerionenkollisionen, die insbesondere am Large Hadron Collider (LHC) oder am Relativistic Heavy Ion Collider (RHIC) durchgeführt werden.
In dieser Arbeit soll ein Beitrag von theoretischer Seite aus hinsichtlich eines besseren Verständnisses dieser Schwerionenkollisionen und der zugrundeliegenden QCD erbracht werden. Der Fokus liegt dabei auf dem Isotropisierungsprozess unmittelbar nach der Kollision der beiden Kerne.
Neben etlichen effektiven Theorien, die sehr gute Ergebnisse in den entsprechenden Grenzbereichen liefern, ist die Beschreibung der QCD im Rahmen der Gittereichtheorie (Gitter-QCD) die am meisten etablierte. Diese beinhaltet in den meisten Fällen einen Übergang zur euklidischen Raumzeit, da somit ein Auswerten der hochdimensionalen Pfadintegrale mithilfe von Monte-Carlo-Simulation basierend auf dem sogenannten Importance Sampling ermöglicht wird. Aufgrund der Komplexwertigkeit der euklidischen Zeitkomponente ist man jedoch an das Studieren von statischen Observablen gebunden. Da wir aber gerade an einer Zeitentwicklung des Systems interessiert sind, sehen wir von dem Übergang zur euklidischen Raumzeit ab, was den Namen “real-time” im Titel der Arbeit erklärt.
Wir folgen dem sogenannten Hamilton-Ansatz und leiten damit Feldgleichungen in Form von partiellen Differentialgleichungen her, die wir dann mit den Methoden der Gitter-QCD numerisch lösen. Dabei bedienen wir uns der effektive Theorie des Farb-Glas-Kondensats (CGC, aus dem Englischen: “Color Glass Condensate”), um geeignete Anfangsbedingungen zu erhalten. Genauer gesagt basieren unsere Gitter-Anfangsbedingungen auf dem McLerran-Venugopalan-Modell (MV-Modell), das eine klassische Approximation in niedrigster Ordnung darstellt und nur Beiträge rein gluonischer Felder berücksichtigt.
Die klassische Näherung sowie das Vernachlässigen der fermionischen Felder wird insbesondere mit den hohen Besetzungszahlen der Feldmoden begründet. Einerseits dominieren Infrarot-Effekte, welche klassischer Natur sind, und andererseits ist dadurch der Einfluss der Fermionen, die dem Pauli-Prinzip gehorchen, unterdrückt. Gerade bei letzterer Aussage fehlt es jedoch an numerischen Belegen. Wir erweitern daher die klassische MV-Beschreibung durch stochastische Gitter-Fermionen, um diesem Punkt nachzugehen. Da sich Fermionen nicht klassisch beschreiben lassen, spricht man hierbei oft von einem semi-klassischen Ansatz.
Eines der Hauptziele dieser Arbeit liegt darin, den Isotropisierungsprozess, der bislang noch viele Fragen aufwirft, aber unter anderem Voraussetzung für das Anwenden von hydrodynamischen Modellen ist, zu studieren. Wir legen dabei einen besonderen Fokus auf die systematische Untersuchung der verschiedenen Parameter, die durch die CGC-Anfangsbedingungen in unsere Beschreibung einfließen, und deren Auswirkungen auf etwa die Gesamtenergiedichte des Systems oder die zugehörigen Isotropisierungszeiten. Währenddessen überprüfen wir zudem den Einfluss von unphysikalischen Gitter-Artefakten und präsentieren eine eichinvariante Methode zur Analyse der Güte unserer klassischen Näherung. Die Zeitentwicklung des Systems betrachten wir dabei sowohl in einer statischen Box als auch in einem expandierenden Medium, wobei Letzteres durch sogenannte comoving Koordinaten beschrieben wird. Zudem liefern wir einen Vergleich von der realistischen SU(3)-Eichgruppe und der rechentechnisch ökonomischeren SU(2)-Eichgruppe.
Mit unseren numerischen Ergebnissen zeigen wir, dass das System hochempfindlich auf die verschiedenen Modellparameter reagiert, was das Treffen quantitativer Aussagen in dieser Formulierung deutlich erschwert, insbesondere da einige dieser Parameter rein technischer Natur sind und somit keine zugehörigen physikalisch motivierten Größen, die den Definitionsbereich einschränken könnten, vorhanden sind. Es ist jedoch möglich, die Anzahl der freien Parameter zu reduzieren, indem man ihren Einfluss auf die Gesamtenergie des Systems analysiert und sich diesen zunutze macht. Dadurch gelingt es uns mithilfe von Konturdiagrammen einige Abhängigkeiten zu definieren und somit die Unbestimmtheit des Systems einzuschränken. Des Weiteren finden wir dynamisch generierte Filamentierungen in der Ortsdarstellung der Energiedichte, die ein starkes Indiz für die Präsenz von sogenannten chromo-Weibel-Instabilitäten sind. Unsere Studie des fermionischen Einflusses auf den Isotropisierungsprozess des CGC-Systems weist auf, dass dieser bei kleiner Kopplung vernachlässigbar ist. Bei hinreichend großen Werten für die Kopplungskonstante sehen wir allerdings einen starken Effekt hinsichtlich der Isotropisierungszeiten, was ein bemerkenswertes Resultat ist.
Particle physics is living it’s golden age: petabytes of high precision data are being recorded at experimental facilities such as the Relativistic Heavy Ion Collider (RHIC) and the Large Hadron Collider (LHC). Despite the significant theoretical progress achieved in the last years the complete understanding of the internal structure of protons, not computable with perturbative QCD, remains as one of the most challenging unsolved problems in the physics of elementary interactions. Besides its fundamental interest, pinning down the relevant degrees of freedom and their properties, such as their spatial distribution, has profound implications in several phenomenological aspects of high-energy collisions. Currently one of the subjects undergoing intense study is the possibility that droplets of quark-gluon plasma (QGP) are being created not only in heavy ion collisions but in more dilute systems such as high-multiplicity proton-proton interactions. This is a data driven debate as it is rooted in the similar patterns observed across the different collision systems at the LHC (p+p,p+Pb and Pb+Pb) in the flow harmonic analyses: one of the golden probes of QGP formation specially sensitive to the initial collision geometry. Another domain in which the proton structure plays a central role is the description of multi-parton interactions, the mechanism that dominates the underlying event at LHC energies, in Monte Carlo event generators. All in all a precise characterization of the hadronic structure is a crucial ingredient of the physics program of the LHC.
A full characterization of a hadron would require momentum, spatial and spin information, the so-called Wigner distribution. So far obtaining this information experimentally has not been achieved. From a theoretical point of view several complications arise such as non-universality and breaking of factorization theorems. Then, in general, the description of the hadron structure relies on phenomenological tools that require theoretical modeling constrained by experimental data. The main goal of this thesis to characterize the transverse structure of the proton. For that purpose, a wide variety of phenomenological problems that are sensitive to the proton structure have been addressed.
First, elastic scattering data on proton-proton interactions constitutes a powerful probe of the geometry of the collision. A dedicated analysis of this observable focusing on the extraction of the inelasticity density from it at √s=62.5 GeV and √s=7 TeV is presented. In the TeV regime, a unexpected phenomenon, dubbed the hollowness effect, arises: the inelasticity density, a measurement of how effective is the collision producing secondary particles, reaches its maximum at non-zero impact parameter. We provide the first dynamical explanation of the hollowness effect by constructing the elastic scattering amplitude in impact parameter representation according to the Glauber model. For that purpose we relied on a composite description of the proton. More concretely, the relevant degrees of freedom that participate in the scattering process were considered to be gluonic hot spots. The probability distribution for the transverse positions of hot spots inside the proton includes repulsive short-range correlations between all pairs of hot spots controlled by an effective repulsive core rc that effectively enlarges the mean transverse separation distance between them. The main results extracted from this work are as follows. To begin with, we found that our model was not able to describe a growing behavior of the inelasticity density at zero impact parameter in the absence of non-trivial spatial correlations. However, even in the presence of correlations, the emergence of the hollowness effect couldn’t be described when the number of hot spots was smaller than 3. Both features set solid constraints in the proton structure within our model. Finally, we pinpoint the transverse diffusion of the hot spots with increasing collision energy to be the dynamical mechanism underlying the onset of the hollowness effect.
A convenient playground to test further implications of this novel geometric description of the proton are the initial state properties of high energy proton-proton interactions in the context of QGP physics. The parametrization of the geometry of the collision is mandatory in any theoretical model attempting to describe the striking experimental results that suggest collective behavior in proton-proton interactions at the LHC, such as the non-zero value of the flow harmonic coefficients (vn). A quantitative way to characterize the initial geometry anisotropy of the overlap region is to compute the spatial eccentricity moments (εn) that fluctuate on an event by event basis. For that purpose we develop a Monte Carlo Glauber event generator. A systematic investigation of the effect of non-trivial spatial correlations in the spatial eccentricity moments from ISR to LHC energies within our Monte Carlo Glauber approach is presented. We found that both the eccentricity (ε2) and the triangularity (ε3) are affected by the inclusion of short-range repulsive correlations. In particular, the correlated scenario yielded larger values of ε2(3) in ultra-central collisions while reducing them in minimum bias.
Moreover, we explore not only the eccentricities mean but their fluctuations in terms of symmetric cumulants. The experimental measurement by the CMS Collaboration at √s=13 TeV indicates a anti-correlation of v2 and v3 around the same number of tracks in the three collision systems available at the LHC. We lay out, for the first time in the literature, a particular mechanism that permits an anti-correlation of ε2 and ε3 in the highest centrality bins as dictated by data. When modeling the proton as composed by 3 gluonic hot spots, the most common assumption in the literature, we find that the inclusion of spatial correlations is indispensable to reproduce the negative sign. Further, we perform a systematic investigation of the parameter space of the model i.e. radius of the hot spot, radius of the proton, repulsive core and number of hot spots in each proton. Our results suggest that the interplay of the different scales is decisive and confirm the discriminating power of this observable on initial state models. Together with their drastic impact on the description of the hollowness effect and the absolute values of the eccentricities, the symmetric cumulant study adds evidence to the fact that the inclusion of spatial correlations between the sub nucleonic degrees of freedom of the proton modifies the initial state properties of p+p interactions at LHC energies.
Complex I couples the free energy released from quinone (Q) reduction to pump protons across the biological membrane in the respiratory chains of mitochondria and many bacteria. The Q reduction site is separated by a large distance from the proton-pumping membrane domain. To address the molecular mechanism of this long-range proton-electron coupling, we perform here full atomistic molecular dynamics simulations, free energy calculations, and continuum electrostatics calculations on complex I from Thermus thermophilus. We show that the dynamics of Q is redox-state-dependent, and that quinol, QH2, moves out of its reduction site and into a site in the Q tunnel that is occupied by a Q analog in a crystal structure of Yarrowia lipolytica. We also identify a second Q-binding site near the opening of the Q tunnel in the membrane domain, where the Q headgroup forms strong interactions with a cluster of aromatic and charged residues, while the Q tail resides in the lipid membrane. We estimate the effective diffusion coefficient of Q in the tunnel, and in turn the characteristic time for Q to reach the active site and for QH2 to escape to the membrane. Our simulations show that Q moves along the Q tunnel in a redox-state-dependent manner, with distinct binding sites formed by conserved residue clusters. The motion of Q to these binding sites is proposed to be coupled to the proton-pumping machinery in complex I.
Strong electron correlations can give rise to extraordinary properties of metals with renormalized Landau quasiparticles. Near a quantum critical point, these quasiparticles can be destroyed and non-Fermi liquid behavior ensues. YbRh2Si2 is a prototypical correlated metal exhibiting the formation of quasiparticle and Kondo lattice coherence, as well as quasiparticle destruction at a field-induced quantum critical point. Here we show how, upon lowering the temperature, Kondo lattice coherence develops at zero field and finally gives way to non-Fermi liquid electronic excitations. By measuring the single-particle excitations through scanning tunneling spectroscopy, we find the Kondo lattice peak displays a non-trivial temperature dependence with a strong increase around 3.3 K. At 0.3 K and with applied magnetic field, the width of this peak is minimized in the quantum critical regime. Our results demonstrate that the lattice Kondo correlations have to be sufficiently developed before quantum criticality can set in.
Most of the elements heavier than iron are produced through neutron capture reactions in the s- and r -process. The overall path of the s-process is well understood and can be accurately reproduced in network simulations. However, there are still some neutron capture reactions of unstable nuclei involved in the s-process, which were not yet measured due to the difficulty in producing suitable targets. In those cases, theoretical models have to be used to estimate the missing cross section.
One example is the branching point nucleus 86Rb, whose neutron capture cross section cannot be directly measured due to its short half life of 18.86 days. It is, however, also possible to measure its inverse, the 87Rb(g,n) reaction in order to obtain the 86Rb(n,g) cross section through the principle of detailed balance.
Natural rubidium was irradiated with a quasi-monoenergetic photon beam in the energy range between 10.7 MeV and 16 MeV in order to investigate the photo-dissociation cross section of 87Rb. The results are presented in this thesis. Not only the total cross section of 87Rb(g,n), but also the partial production cross section of the ground and isomeric state of 84Rb through the 85Rb(g,n) reaction was measured.
Not all isotopes can be reached via neutron capture reaction, and are therefore bypassed by the s- and r -process. These 35 proton-rich isotopes are called p-nuclei and are produced in the γ-process by a chain of photo-disintegration reactions in Type II supernovae. Network calculations of Type II supernova show that the γ-process can explain the production of most p-nuclei, but some – especially 92/94Mo and 96/98Ru – are heavily underproduced. While this could be the result of deficiencies in the corresponding stellar models or insufficient knowledge of the involved reaction rates, it is also possible that the missing p-nuclei are synthesized in other production scenarios.
An alternative scenario for 92Mo is the production via a chain of proton capture reactions in Type Ia supernovae. One important reaction in this chain is the 90Zr(p,g) reaction. The reaction cross section was already measured several times, but the results were inconclusive. In the present work, the 90 Zr(p,g) reaction was measured using the in-beam gamma-ray spectroscopy technique and the discrepancies between the data sets could be largely explained.