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In the study of trapped two-component Bose gases, a widely used dynamical protocol is to start from the ground state of a one-component condensate and then switch half the atoms into another hyperfine state. The slightly different intra-component and inter-component interactions can then lead to highly non-trivial dynamics, especially in the density mismatch between the two components, commonly referred to as 'spin' density. We study and classify the possible subsequent dynamics, over a wide variety of parameters spanned by the trap strength and by the inter- to intra-component interaction ratio. A stability analysis suited to the trapped situation provides us with a framework to explain the various types of dynamics in different regimes.
Optogenetic manipulation of neuronal activity through excitatory and inhibitory opsins has become an indispensable experimental strategy in neuroscience research. For many applications bidirectional control of neuronal activity allowing both excitation and inhibition of the same neurons in a single experiment is desired. This requires low spectral overlap between the excitatory and inhibitory opsin, matched photocurrent amplitudes and a fixed expression ratio. Moreover, independent activation of two distinct neuronal populations with different optogenetic actuators is still challenging due to blue-light sensitivity of all opsins. Here we report BiPOLES, an optogenetic tool for potent neuronal excitation and inhibition with light of two different wavelengths. BiPOLES enables sensitive, reliable dual-color neuronal spiking and silencing with single- or two-photon excitation, optical tuning of the membrane voltage, and independent optogenetic control of two neuronal populations using a second, blue-light sensitive opsin. The utility of BiPOLES is demonstrated in worms, flies, mice and ferrets.
Im Rahmen der vorliegenden Arbeit wurde ein Spracherkennungssystem realisiert, das sowohl phonembasierte als auch wortbasierte Modelle zur sprecherunabhängigen Schlüsselworterkennung im Kontext fließender Sprache verwenden kann. Das System erlaubt dabei die Wahl zwischen zwei grundlegend verschiedenen Verfahren: Entweder kann die Bewertung von Äußerungen durch Schlüsselwortmodelle mit gewählten Schwellenwerten verglichen werden, wobei eine Schwellenwertüberschreitung die Erkennung eines Schlüsselwortes signalisiert, oder es werden beliebige Phonemfolgen als Füllmodelle verwendet, die mit den Schlüsselwortmodellen konkurrieren. Der Schlüsselworterkenner kann sowohl zur 1-Schlüsselwort- Erkennung, bei der vorausgesetzt wird, dass sich in jeder Äußerung exakt ein Schlüsselwort befindet, als auch zur n-Schlüsselwort-Erkennung verwendet werden, bei der sich eine beliebige Anzahl Schlüsselwörter in jeder Äußerung befinden kann. Durch eine effiziente Implementation wurde die Fähigkeit zur Echtzeitverarbeitung auf verfügbaren Arbeitsplatzrechnern erreicht.....
Efficient modeling and mitigation of quadrupole errors in synchrotrons and their beam transfer lines
(2023)
This thesis investigates the problem of estimating quadrupole errors on synchrotrons as well as how to minimize the influence of quadrupole errors for beam transfer lines (beamlines). It emphasizes the importance to treat possible error sources in all parts of an accelerator in order to provide constantly high beam quality to the experimental stations. While the presented methods have been investigated by using the example of the SIS18 synchrotron and the HEST beamlines at GSI Helmholtz Centre for Heavy Ion Research, they are equally relevant for the future synchrotrons and beamlines of the Facility for Antiproton and Ion Research in Europe (FAIR).
Part 1 discusses the problem of estimating quadrupole errors via orbit response measurements at synchrotrons. An emphasis is put on investigating the influence of the availability of steerer magnets and beam position monitors (BPMs) on the solvability of the inverse problem as well as on the propagation of measurement uncertainty for the estimation of quadrupole errors. The problem is approached via analytical considerations as well as via dedicated simulation studies. By developing an analytical expression for the Jacobian matrix, the theoretical boundaries for the solvability of the inverse problem are derived. Moreover, it is shown that the analytical expressions for the Jacobian matrix can be used during the fitting procedure to achieve a significant improvement in the computational efficiency by a factor $N_{steerers} \times N_{quadrupoles}$, where $N$ denotes the number of lattice elements of the respective type. The presented results are tested via dedicated measurements at the SIS18 synchrotron.
Part 2 discusses – complementary to part 1 – the influence of quadrupole errors in beam transfer lines with respect to the beam quality requirements given by the experimental stations. A preventive approach is presented which allows to minimize the influence of possible quadrupole errors on the degradation of beam quality. By identifying and selecting robust quadrupole configurations, a stable operation of the beamline can be enabled and the time needed by operators to readjust the beamline parameters can be reduced. The concept of beamline robustness is developed and is studied with the help of dedicated simulations. The simulation results are used to identify certain properties that distinguish robust from nonrobust quadrupole configurations. Also, various methods for improving the computational process of identifying robust quadrupole configurations are presented. The methods and results are tested via dedicated measurements at two different beamlines at GSI Helmholtz Centre for Heavy Ion Research and at Forschungszentrum Jülich.
Inverse modeling of circular lattices via orbit response measurements in the presence of degeneracy
(2023)
The number and location of beam position monitors (BPMs) and steerers with respect to the quadrupoles in a circular lattice can lead to degeneracy in the context of fitting linear optics and extracting lattice information from measured closed orbits. Furthermore, the measurement uncertainties due to the imperfection of BPMs and steerers can be propagated by the fitting process in ways that prohibit the successful extraction of discrepancies between lattice elements in the real machine and their description in the corresponding model. We systematically studied the influence of the placement of BPMs and steerers on the reconstruction of linear optics and corresponding lattice information. The derivative of orbit response coefficients with respect to the quadrupole strengths, the Jacobian, is derived as an analytical formula. This analytical version of the Jacobian is used to further derive the theoretical limitations of fitting linear optics from closed orbits in terms of the placement of BPMs and steerers. It is further demonstrated that when evaluating the Jacobian during the fitting procedure, the analytical version can be used in place of the conventional finite-difference computation. This allows for greatly improved efficiency when computing the Jacobian during each iteration of the fitting procedure. The approach is tested with large-scale simulations and the findings are verified by measurement data taken on SIS18 synchrotron at GSI Helmholtz Centre for Heavy Ion Research. The presented methods are of general nature and can be applied to other accelerator lattices as well. The fitting procedure by using the analytical Jacobian is tested in conjunction with various methods for mitigating quasidegeneracy and the results agree with those obtained by using the conventional Jacobian via finite-difference approximation.
Neural networks have been recently proposed as variational wave functions for quantum many-body systems [G. Carleo and M. Troyer, Science 355, 602 (2017)]. In this work, we focus on a specific architecture, known as Restricted Boltzmann Machine (RBM), and analyse its accuracy for the spin-1/2 J1−J2 antiferromagnetic Heisenberg model in one spatial dimension. The ground state of this model has a non-trivial sign structure, especially for J2/J1>0.5, forcing us to work with complex-valued RBMs. Two variational Ans\"atze are discussed: one defined through a fully complex RBM, and one in which two different real-valued networks are used to approximate modulus and phase of the wave function. In both cases, translational invariance is imposed by considering linear combinations of RBMs, giving access also to the lowest-energy excitations at fixed momentum k. We perform a systematic study on small clusters to evaluate the accuracy of these wave functions in comparison to exact results, providing evidence for the supremacy of the fully complex RBM. Our calculations show that this kind of Ans\"atze is very flexible and describes both gapless and gapped ground states, also capturing the incommensurate spin-spin correlations and low-energy spectrum for J2/J1>0.5. The RBM results are also compared to the ones obtained with Gutzwiller-projected fermionic states, often employed to describe quantum spin models [F. Ferrari, A. Parola, S. Sorella and F. Becca, Phys. Rev. B 97, 235103 (2018)]. Contrary to the latter class of variational states, the fully-connected structure of RBMs hampers the transferability of the wave function from small to large clusters, implying an increase of the computational cost with the system size.
We suggest to explore an entirely new method to experimentally and theoretically study the phase diagram of strongly interacting matter based on the triple nuclear collisions (TNC).We simulated the TNC using the UrQMD 3.4 model at the beam center of- mass collision energies √SNN = 200 GeV and √SNN = 2.76 TeV. It is found that in the most central and simultaneous TNC the initial baryonic charge density is about 3 times higher than the one achieved in the usual binary nuclear collisions at the same energies. As a consequence, the production of protons and Λ-hyperons is increased by a factor of 2 and 1.5, respectively. Using the MIT Bag model equation we study the evolution of the central cell in TNC and demonstrate that for the top RHIC energy of collision the baryonic chemical potential is 2-2.5 times larger than the one achieved in the binary nuclear collision at the same time of reaction. Based on these estimates, we show that TNC offers an entirely new possibility to study the QCD phase diagram at very high baryonic charge densities.
The radiative electron capture (REC) into the K shell of bare Xe ions colliding with a hydrogen gas target has been investigated. In this study, the degree of linear polarization of the K-REC radiation was measured and compared with rigorous relativistic calculations as well as with the previous results recorded for U92+. Owing to the improved detector technology, a significant gain in precision of the present polarization measurement is achieved compared to the previously published results. The obtained data confirms that for medium-Z ions such as Xe, the REC process is a source of highly polarized x rays which can easily be tuned with respect to the degree of linear polarization and the photon energy. We argue, in particular, that for relatively low energies the photons emitted under large angles are almost fully linear polarized.
Seit hundert Jahren ist bekannt, dass die mikroskopische Welt der Atome und Moleküle von den Gesetzen der Quantenphysik regiert wird. Lange Zeit galten Quantenphänomene als verworren und unkontrollierbar. Heute arbeiten Physikerinnen und Physiker daran, unter Nutzung quantenphysikalischer Effekte Materialien mit neuartigen Eigenschaften zu kreieren.
The regeneration of hadronic resonances is discussed for heavy ion collisions at SPS and SIS-300 energies. The time evolutions of Delta, rho and phi resonances are investigated. Special emphasize is put on resonance regeneration after chemical freeze-out. The emission time spectra of experimentally detectable resonances are explored.
We predict transverse and longitudinal momentum spectra and yields of rho 0 and omega mesons reconstructed from hadron correlations in C+C reactions at 2~AGeV. The rapidity and pT distributions for reconstructable rho 0 mesons differs strongly from the primary distribution, while the omega's distributions are only weakly modified. We discuss the temporal and spatial distributions of the particles emitted in the hadron channel. Finally, we report on the mass shift of the rho 0 due to its coupling to the N*(1520), which is observable in both the di-lepton and pi pi channel. Our calculations can be tested with the Hades experiment at GSI, Darmstadt.
These proceedings will cover various studies of hadronic resonances within the UrQMD transport model. After a brief explanation of the model, various observables will be highlighted and the chances for resonance reconstruction in hadronic channels will be discussed. Possible signals of chiral symmetry restoration will be investigated for feasibility.
The following thesis is the description and the analysis of time resolution measurements of the plastic scintillator protorypes bar with PMT (photomultiplier tube) readout, performed with a 31 MeV electron beam at the HZDR (Helmholtz-Zentrum Dresden-Rossendorf) [1]. Similar bars will be used as building blocks for the NeuLAND detector (new large area neutron detector) - a ToF (time of flight) wall within the R3B setup (Reactions with Relativistic Radioactive Beams [2]) at the future FAIR facility (GSI Darmstadt [3]). The superconducting ELBE (electron linear-accellerator for beams of high brilliance and low emittance) was used as an electron source. The scintillation material used was RP408.
Two series of measurements were made within three months. In the first series, three bars of different sizes (200 x 5 x 5 cm3; 200 x 3 x 3 cm3; 300 x 5 x 5 cm3, the latter was made by coupling one 100 cm bar with a 200 cm bar using silicon grease) were used in the experiment consecutively. They had one Hamamatsu R8619 photomultiplier tube with an active diameter of 22 mm attached to each side with silicon grease. A measurement with the 200 x 5 x 5 cm3 bar without silicon grease was also performed.
In the second series, two equal scintillator bars (270 x 5 x 5 cm3 with a 10 cm light guide) on each side were used. Measurements with and without silicon coupling as well as with two different types of PMTs (R8619 and R2059) were executed.
Time and charge signals were processed with the TACQUILA electronic board. The time resolution was measured with the very precise pulsed electron signal of the accelerator. The time resolution measurements resulted in ρ200x5x5 ~ 159 ps; ρ200x5x5,no silicon ~ 162 ps; ρ200x3x3 ~ 153 ps; ρ300x5x5 ~ 204 ps.
For the second date they resulted in ρR8619 ~ 149 ps; ρR8619, no silicon ~ 175 ps; ρR2059 ~ 141 ps.
More tests and analysis is required until the results are definite.
Die Entstehung der Elemente im Universum wird auf eine Vielzahl von Prozessen zurückgeführt, die sowohl in Urknall - als auch in stellaren Szenarien angesiedelt werden. Die Kenntnis der dort ablaufenden Reaktionen und deren Raten ermöglicht es die zugrundeliegenden Modelle einzugrenzen und somit genauere Aussagen über die Plausibilität der Szenarien zu treffen. Ein Teil dieser Prozesse stützt sich auf Neutroneneinfänge an Atomkernen, wodurch die Massezahl des Ausgangskerns erhöht wird.
Die Aktivierungsmethode ermöglicht die Bestimmung der Wahrscheinlichkeit eines Neutroneneinfangs, sofern der Zielkern eine detektierbare Radioaktivität aufweist. Die experimentelle Untersuchung einer Reaktion mit einem kurzlebigen Produktkern ist eine besondere Herausforderung, da bei langen Aktivierungen zwar viele Einfänge stattfinden, die meisten Produktkerne jedoch schon während der Aktivierung zerfallen. Ein probates Mittel um genügend Zerfälle des Produktkerns beobachten zu können ist die zyklische Aktivierung, wobei die Probe in mehrfachen Wiederholungen kurz bestrahlt und ausgezählt wird.
Im Rahmen dieser Arbeit wurden zwei verschiedene Anwendungen der zyklischen Aktivierung behandelt.
Eine vom Paul Scherrer Institut Villigen bereitgestellte Probe von 10Be wurde am TRIGA Reaktor der Johannes Gutenberg - Universität Mainz mit Neutronen aktiviert. Über die Cadmiumdifferenzmethode konnte der thermische und der epithermische Anteil der Neutronen separiert werden und dadurch sowohl der thermische Wirkungsquerschnitt als auch das Resonanzintegral für die Reaktion 10Be(n,γ)11Be bestimmt werden.
Am Institut für Kernphysik der Goethe Universität Frankfurt wurde mit einem Van - de - Graaff - Beschleuniger über die 7Li(p,n)7Be Reaktion ein quasistellares Neutronenspektrum mit kBT ≈ 25 keV erzeugt. Für die zyklische Aktivierung von Proben wurde die Infrastruktur in Form einer automatisiert ablaufenden Vorrichtung zur Bestrahlung und Auszählung geplant und umgesetzt. In diesem Rahmen wurden die über das Spektrum gemittelten Neutroneneinfangsquerschnitte für verschiedene Reaktionen bestimmt. Für 19F(n,γ)20F konnte der Gesamteinfangsquerschnitt bestimmt werden. Für die Reaktion 45Sc(n,γ)46Sc wurde der partielle Wirkungsquerschnitt in den 142,5 keV Isomerzustand gemessen. Aus der 115In(n,γ)116In Reaktion konnten die partiellen Querschnitte in die Isomerzustände bei 289,7 keV, 127,3 keV sowie den Grundzustand bestimmt werden.
Außerdem wurde mit einer Hafniumprobe die partiellen Einfangsquerschnitte in den 1147,4 keV Isomerzustand von 178Hf und in den 375 keV Isomerzustand von 179Hf gemessen.
A model for the quantum yield of the coloration caused by UV-light in spiropyran layers is described. This model allows to calculate the sensitivity of layers having different compositions. The mechanism concerning the stability of the coloration is essentially clarified. Calculations of the stability for layers of different compositions are possible by a model describing the mechanism approximately.
The HITRAP linear decelerator currently being set up at GSI will provide slow, few keV/u highly charged ions for atomic physics experiments. The expected beam intensity is up to 105 ions per shot. To optimize phase and amplitude of the RF systems intensity, bunch length and kinetic energy of the particles need to be monitored. The bunch length that we need to fit is about 2 ns, which is typically measured by capacitive pickups. However, they do not work for the low beam intensities that we face. We investigated the bunch length with a fast CVD diamond detector working in single particle counting mode. Averaging over 8 shots yields a clear, regular picture of the bunched beam. Energy measurements by capacitive pickups are limited by the presence of intense primary and partially decelerated beam and hence make tuning of the IH-structure impossible. The energy of the decelerated fraction of the beam behind the first deceleration cavity was determined to about 10 % accuracy with a permanent dipole magnet combined with a MCP. Better detector calibration should help reaching the required 1%. Design of the detectors as well as the results of the measurements will be presented.
Ziel der durchgeführten Experimente dieser Arbeit war es, den Versuch zu unternehmen, Cooper-Paare als Träger des supraleitenden Stroms direkt mit Hilfe des Photoelektrischen Effektes nachzuweisen. Die Methode der koinzidenten Photoelektronenspektroskopie zielt dabei auf den Nachweis von zwei kohärent emittierten Elektronen durch die Wechselwirkung mit einem Photon ab. Da elektrostatische Analysatoren typischerweise nur einen sehr kleinen Raumwinkel erfassen, was mit sehr geringen Koinzidenzraten einhergeht, ist im Zusammenhang mit dieser Arbeit ein Flugzeitprojektionssystem entwickelt worden, welches nahezu den gesamten Raumwinkel auf einem ortsauflösenden Detektor abbildet. Die zur Messung erforderliche gepulste Lichtquelle in Form von spezieller Synchrotronstrahlung ist so schwach eingestellt worden, daß nur vereinzelt Photonen auf die Probe gelangen konnten. Spektroskopiert wurde neben Testmessungen an Silberschichten sowohl ein Blei-Einkristall als Vertreter der klassischen BCS-Supraleiter als auch einkristallines Bi2Sr2CaCu2O8 aus der Gattung der Hochtemperatursupraleiter. Mit Anregungsenergien bis 40 eV konnte gezeigt werden, daß hinreichend glatte und saubere Oberflächen in der supraleitenden Phase innerhalb des Auflösevermögens von ungefähr 0.5 eV keine erkennbaren, signifikanten Unterschiede im Vergleich zur normalleitenden Phase aufweisen. Neben diesen Untersuchungen ist weiterhin ausführlich die einfache Photoemission an den verschiedenen Proben und insbesondere im Falle des Bleikristalls behandelt, da hier keine vergleichbaren Resultate bekannt sind. Dabei wird der gesamte Impulsraum besprochen und die Fermi-Fläche als dreidimensionales Modell erstellt, mit dessen Hilfe die Meßergebnisse diskutiert werden. In den theoretischen Beschreibungen sind verschiedene Modelle zur Cooper-Paar-Emission vorgestellt, wobei beispielsweise dem Impulsaustausch mit dem Kristall eine besondere Rolle beigemessen wird, da dieser bei direkten Anregungen nur über diskrete Gittervektoren erfolgen kann.
Durch Messen der vollständigen Impulsvektoren beider Coulomb-explodierender, einfachgeladener Fragmente eines doppelionisierten, diatomaren, homonuklearen Moleküls (H2, N2, O2) können verschiedene Ionisationsprozesse identifiziert werden. Bei der sogenannten COLd Target Recoil Ion Momentum Spectroskopy (COLTRIMS) wird ein überschall Gasjet mit ultrakurzen, hochintensiven Laserpulsen penetriert. Aus den gemessenen Fragmentimpulsen kann die freigesetzte kinetische Energie, sowie die ursprüngliche Lage der Molekülachse im Laborsystem berechnet werden, woraus winkelabhängige Explosionswahrscheinlichkeiten abgeleitet werden können, die unter bestimmten Bedingungen die orbitale Symmetrie der Moleküle wiederspiegeln. Unter Benutzung verschiedener Pulslängen des Lasers (35 fs und 8 fs) und Variation der Polarisation (linear, zirkular) koennen Ionisationsmechanismen wie rescattering oder sequentielle Ionisation identifiziert werden.