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In this work we investigate phenomenological aspects of an anisotropic quark-gluon plasma. In the first part of this thesis, we formulate phenomenologicalmodels that take into account the momentumspace anisotropy of the system developed during the expansion of the fireball at early-times. By including the proper-time dependence of the parton hard momentum scale, phard(), and the plasma anisotropy parameter, Xi, the proposed models allow us to interpolate from 0+1 pre-equilibrated expansion at early-times to 0+1 ideal hydrodynamics at late times. We study dilepton production as a valuable observable to experimentally determine the isotropization time of the system as well as the degree of anisotropy developed at early-times. We generalize our interpolating models to include the rapidity dependence of phard and consider its impact on forward dileptons. Next, we discuss how to constrain the onset of hydrodynamics by demanding two requirements of the solutions to the equations of motion of viscous hydrodynamics. We show this explicitly for 0+1 dimensional 2nd-order conformal viscous hydrodynamics and find that the initial conditions are non-trivially constrained. Finally, we demonstrate how to match the initial conditions for 0+1 dimensional viscous hydrodynamics from pre-equilibrated expansion. We analyze the dependence of the entropy production on the pre-equilibrium phase and discuss limitations of the standard definitions of the non-equilibrium entropy in kinetic theory.
In this thesis we have studied the physics of different ultracold Bose-Fermi mixtures in optical lattices, as well as spin 1=2 fermions in a harmonic trap. To study these systems we generalized dynamical mean-field theory for a mixture of fermions and bosons, as well as for an inhomogeneous environment. Generalized dynamical mean-field theory (GDMFT) is a method that describes a mixture of fermions and bosons. This method consists of Gutzwiller mean-field for the bosons, and dynamical mean-field theory for the fermions, which are coupled on-site by the Bose-Fermi density-density interaction and possibly a Feshbach term which converts a pair of up and down fermions into a molecule, i.e. a boson. We derived the self-consistency equations and showed that this method is well-controlled in the limit of high lattice coordination number z. We develop real-space dynamical mean-field theory for studying systems in an inhomogeneous environment, e.g. in a harmonic trap. The crucial difference compared to standard DMFT is that we are taking into account that different sites are not equivalent to each other and thus take into account the inhomogeneity of the system. Different sites are coupled by the real-space Dyson equation. ...
Quantum entanglement plays a basic role in quantum information science. The creation of entanglement between qubits is of fundamental importance for further computation processing like quantum computation, quantum cryptography, quantum teleportation, quantum computers… We present here a symmetric electron-electron scattering experiment to determine the experimental parameters which are necessary to produce a source of entangled electrons. In this Moeller scattering experiment the electrons differ from each other only by their spin direction. At these conditions a spin entanglement of the scattered electrons is expected. To demonstrate the spin entanglement, a single particle resolved spin measurement of the electrons has to be performed. A high ratio of measured coincidences compare to random could be demonstrated. It is shown, that this ratio is related to an experiment depended nearly constant efficiency for the coincidence detection. In order to proof the spin entanglement, the goal is to measure the final polarization state of the electrons at different scattering directions to observe a spin anti correlation between these spin states of the Moeller electrons. The usual method to determine the electron polarization is based on an asymmetric scattering experiment with a high Z target. This scattering may yield an asymmetry due to a different spin-orbit coupling of the electrons. The main problem of polarized electron studies at keV-particle energy is the low efficiency of usual spin polarimeters. This low efficiency impedes or prevents electron spin resolved coincidence measurements because of necessarily induced random coincidences. To enhance the efficiency of the spin detection, a new compact mini-Mott spin analyzer has been developed. Due to a compact small size of this analyzer, a higher efficiency is obtained now, which is a prerequisite to the electron spin resolved coincidence measurements. Till date, the asymmetry measurement have been performed where one Mott analyzer rotated by an angle around the axis. The reducing asymmetry is in agreement with a prediction of quantum mechanic; however, the large systematic errors of the measurement have been estimated. As a next step for investigation of spin entanglement it is planned to increase the overall efficiency of the experiment by having higher initial energy and minimize error of the measurement by applying new kind of detectors.
Energy and environment are two major concerns in the 21st century. At present, the energy required for the daily life still mainly relies on the traditional fossil fuel resources, but the caused air pollution problem and greenhouse effect have seriously threatened the sustainable development of mankind. Another adopted energy source which can provide a large fraction of electricity for the world is the nuclear fission reaction. However, the increasing high-radioactive spent nuclear fuels, which half-lives are usually >1 million years, are becoming the hidden perils to the earth. A great advance in accelerator physics and technology opens an opportunity to solve this dilemma between man and nature, because powerful accelerator-based neutron sources can play important roles for clean nuclear power production, for example: - The Accelerator-Driven System (ADS) can serve as an easy control of a sub-critical fission reactor so that the nuclear fuels will be burnt more completely and safely. - The EUROTRANS project launched by EU is investigating another application of the ADS technology to reduce the radiotoxicity and the volume of the existing nuclear waste greatly and quickly in a transmutation way. - The developing international IFMIF plant will be used to test and qualify reactor materials for future fusion power stations, which can produce much cleaner nuclear electricity more efficiently than the fission ones. Therefore, the R&D of high-power driver linacs (HPDL) is of a worldwide importance. As the proverb said, "everything is hard at the beginning", the front end is the most difficult part for realizing an HPDL machine. Based on the RFQ and H-type DTL structures, this dissertation is dedicated to study the beam dynamics in the presence of significantly strong space-charge effects while accelerating intense hardon beams in the low- and medium-beta-region. Besides the 5mA/30mA, 17MeV proton injector (RFQ+DTL) and the 125mA, 40MeV deuteron DTL of the above-mentioned EUROTRANS and IFMIF facilities, a 200mA, 700keV proton RFQ has been also intensively studied for a small-scale but ultra-intense neutron source FRANZ planned at Frankfurt University. The most remarkable properties of the FRANZ RFQ and the IFMIF DTL are the design beam intensities, 200mA and 125mA, which are the record values for the proton and deuteron linacs, respectively. Though the design intensities for the two development stages, XT-ADS (5mA) and EFIT (30mA), of the EUROTRANS injector are well within the capability of the modern RF linac technology, the special design concept for an easy upgrade from XT-ADS to EFIT brings unusual challenges to realize a linac layout which allows flexible operation with different beam intensities. To design the 200mA FRANZ RFQ and the two-intensity EUROTRANS RFQ, the classic LANL (Los Alamos National Laboratory) Four-Section Procedure, which was developed by neglecting the space-charge forces, is not sufficient anymore. Abandoning the unreasonable constant- B (constant-transverse-focusing-strength) law and the resulting inefficient evolution manners of dynamics parameters adopted by the LANL method, a new design approach so-called "BABBLE", which can provide a "Balanced and Accelerated Beam Bunching at Low Energy", has been developed for intense beams. Being consistent with the beam-development process including space-charge effects, the main features of the "BABBLE" strategy (see Pages 55-58) are: 1) At the entrance, the synchronous phase is kept at = phi s = -90° while a gradual increase in the electrode modulation is started so that the input beam can firstly get a symmetrical and soft bunching within a full-360° phase acceptance. 2) In the following main bunching section, B is increasing to balance the stronger and stronger transverse defocusing effects induced by the decreasing bunch size so that the bunching speed can be fast and safely increased. 3) When the real acceleration starts, the quickly increased beam velocity will naturally weaken the transverse defocusing effects, so B is accordingly falling down to avoid longitudinal emittance growths and to allow larger bore apertures. Taking advantage of the gentle initial bunching and the accelerated main bunching under balanced forces enabled by the "BABBLE" strategy, a 2m-long RFQ with beam transmission in excess of 98% and low emittance growths has been designed for FRANZ, and a 4.3m-long RFQ with almost no beam losses and flat emittance evolutions at both 5mA and 30mA has been designed for EUROTRANS. All design results have proven that the "BABBLE" strategy is a general design approach leading to an efficient and robust RFQ with good beam quality in a wide intensity-range from 0mA to 200mA (even higher). To design the IFMIF DTL and the injector DTL part of the EUROTRANS driver linac, which have been foreseen as the first real applications of the novel superconducting CH-DTL structure, intensive attempts have been made to fulfill the design goals under the new conditions, e.g. long drift spaces, SC transverse focusing elements and high accelerating gradients. For the IFMIF DTL, the preliminary IAP design has been considerably improved with respect to the linac layout as well as the beam dynamics. By reserving sufficient drift spaces for the cryosystem, diagnostic devices, tuner and steerer, introducing SC solenoid lenses and adjusting the Linac Design for Intense Hadron Beams accelerating gradients and accordingly other configurations of the cavities (see Pages 78-80), a more realistic, reliable and efficient linac system has been designed. On the other hand, the specifications and positions of the transverse focusing elements (see Pages 81-82) as well as the phase- and energy-differences between the bunch-center particle and the synchronous particle at the beginning of the phi s=0° sections have been totally redesigned (see Pages 83-84) resulting in good beam performances in both radial and longitudinal planes. For the EUROTRANS injector DTL, in addition to the above-mentioned procedures, extra optimization concepts to coordinate the beam dynamics between two intensities, such as employing short adjustable rebunching cavities with phi s = -90° (see Page 116), have been applied. ...
In this thesis, we studied the single impurity Anderson model and developed a new and fast impurity solver for the dynamical mean field theory (DMFT). Using this new impurity solver, we studied the Hubbard model and periodic Anderson model for various parameters. This work is motivated by the fact that the dynamical mean field theory is widely used for the studies of strongly correlated systems, and the most frequently used methods, e.g. the quantum Monte-Carlo method (QMC), and the exact digonalization method are much CPU time consuming and usually limited by the available computers. Therefore, a fast and reliable impurity solver is needed. This new impurity solver was explored based on the equation-of-motion method (also called Green's function and decoupling method in some literature). Using the retarded Green's function, we first derived the equations of motion of Green's functions. Then, we employed a decoupling scheme to close the equations. By solving self-consistently the obtained closed set of integral equations, we obtained the single particle Green's function for the single impurity Anderson model. After that, the single impurity Anderson model was solved along with self-consistency conditions within the framework of DMFT. In this work, we studied and compared two decoupling schemes. Moreover, we also derived possible higher order approximations which will be tested in future work. Besides the theoretical work, we tested the method in numerical calculations. The integral equations are first solved by iterative methods with linear mixing and Broyden mixing, respectively. However, these two methods are not sufficient for finding the self-consistent solutions of the DMFT equations because converged results are difficult to obtain. Moreover, the computing speed of the two methods is also not satisfactory. Especially the iterative method with linear mixing costs always a lot of CPU time due to the required small mixing. Hence, we developed a new method, which is a combination of genetic algorithm and iterative method. This new method converges very fast and removes artifacts appearing in the results from the iterative method with linear and Broyden mixing. It can directly operate on the real axis, where no numerical error from the high frequency tail corrections and the analytical continuation is introduced. In addition, our new technique strongly improves the precision of the numerical results by removing the broadening. With this newly developed impurity solver and numerical technique, we studied the single impurity Anderson model, the single band Hubbard model and the periodic Anderson model with arbitrary spin and orbital degeneracy N on the real axis. For the single impurity Anderson model, the spectral functions are calculated for the infinite and finite Coulomb interaction strength. We also studied the spectral functions in dependence of the parameters of impurity position and hybridization. For the Hubbard model, we studied the bandwidth control and filling control Mott metal-insulator transition for spin and orbital degeneracy N = 2. It gives qualitatively the critical value of Coulomb interaction strength for the Mott metal-insulator transition, and the spectral functions which are comparable to those obtained in QMC and numerical renormalization group methods. We also studied the quasiparticle weight and the self-energy in metallic states. The latter shows almost Fermi liquid behavior. At last we calculated the densities of states for the Hubbard model with arbitrary spin and orbital degeneracy N. The periodic Anderson model (PAM) is also studied as another important lattice model. It was solved for various combinations of parameters: the Coulomb interaction strength, the impurity position, the center position of the conduction band, the hybridization, the spin and orbital degeneracy. The PAM results represents the physics of impurities in a metal. In short, our method works for the Hubbard model and the periodic Anderson model in a large range of parameters, and gives good results. Therefore, our impurity solver could be very useful in calculations within LDA+DMFT. Finally, we also made a preliminary investigation of the multi-band system based on the success in single band case. We first studied the two-band system in a simplified treatment by neglecting the interaction between the two bands through the bath. This has given promising numerical results for the two-band Hubbard model. Moreover, we have studied theoretically the two-band system with mean field approximation and Hubbard-I approximation in dealing with the higher order cross Green's functions which are related to both the two bands. In the mean field approximation, we even generalized the two-band system to arbitrary M=N/2 band system. Potential improvement can be carried out on the basis of this work.
The current thesis is devoted to a systematic study of fluctuations and correlations in heavy-ion collisions, which might be considered as probes for the phase transition and the critical point in the phase diagram, within the Hadron-String- Dynamics (HSD) microscopic transport approach. This is a powerful tool to study nucleus-nucleus collisions and allows to completely simulate experimental collisions on an event-by-event basis. Thus, the transport model has been used to study fluctuations and correlations including the influence of experimental acceptance as well as centrality, system size and collision energy. The comparison to experimental data can separate the effects induced by a phase transition since there is no phase transition in the HSD version used here. Firstly the centrality dependence of multiplicity fluctuations has been studied. Different centrality selections have been performed in the analysis in correspondence to the experimental situation. For the fixed target experiment NA49 events with fixed numbers of the projectile participants have been studied while in the collider experiment PHENIX centrality classes of events have been defined by the multiplicity in certain phase space region. A decrease of participant number fluctuations (and thus volume fluctuations) in more central collisions for both experiments has been obtained. Another area of this work addresses to transport model calculations of multiplicity fluctuations in nucleus-nucleus collisions as a function of colliding energy and system size. This study is in full correspondence to the experimental program of the NA61 Collaboration at the SPS. Central C+C, S+S, In+In, and Pb+Pb nuclear collisions at Elab = 10, 20, 30, 40, 80, 158 AGeV have been investigated. The expected enhanced fluctuations - attributed to the critical point and phase transition - can be observed experimentally on top of a monotonic and smooth ‘hadronic background’. These findings should be helpful for the optimal choice of collision systems and collision energies for the experimental search of the QCD critical point. Other observables are fluctuations of ratios of hadrons (e.g. pions, kaons, protons, etc.) which are not so much affected by volume fluctuations. In particular HSD results for the kaon-to-pion ratio fluctuations, which has been regarded as promising observable for a long time, are presented from low SPS energies up to high energies at RHIC. In addition to the HSD calculations statistical model is also used in terms of microcanonical, canonical and grand canonical ensembles. Further a study of the system size event-by-event fluctuations causing rapidity forward-backward correlations in relativistic heavy-ion collisions is presented. The HSD simulations reveal strong forward-backward correlations and reproduce the main qualitative features of the STAR data in A+A collisions at RHIC energies. It has been shown that strong forward-backward correlations arise due to an averaging over many different events that belong to one centrality bin. An optimization of the experimental selection of centrality classes is presented, which is relevant for the program of the NA61 collaboration at CERN, the low-energy program at RHIC, as well as future experiments at FAIR.
Kaon and pion production in centrality selected minimum bias Pb+Pb collisions at 40 and 158A GeV
(2009)
Results on charged kaon and negatively charged pion production and spectra for centrality selected Pb+Pb mininimum bias events at 40 and 158A GeV have been presented in this thesis. All analysis are based on data taken by the NA49 experiment at the accelerator Super Proton Synchrotron (SPS) at the European Organization for Nuclear Research (CERN) in Geneva, Switzerland. The kaon results are based on an analysis of the mean energy loss <dE/dx> of the charged particles traversing the detector gas of the time projection chambers (TPCs). The pion results are from an analysis of all negatively charged particles h- corrected for contributions from particle decays and secondary interactions. For the dE/dx analysis of charged kaons, main TPC tracks with a total momentum between 4 and 50 GeV have been analyzed in logarithmic momentum log(p) and transverse momentum pt bins. The resulting dE/dx spectra have been fitted by the sum of 5 Gaussians, one for each main particle type (electrons, pions, kaons, protons, deuterons). The amplitude of the Gaussian used for the kaon part of the spectra has been corrected for efficiency and acceptance and the binning has been transformed to rapidity y and transverse momentum pt bins. The multiplicity dN/dy of the single rapidity bins has been derived by summing the measured range of the transverse momentum spectra and an extrapolation to full coverage with a single exponential function fitted to the measured range. The results have been combined with the mid-rapidity measurements from the time-of-flight detectors and a double Gaussian fit to the dN/dy spectra has been used for extrapolation to rapidity outside of the acceptance of the dE/dx analysis. For the h- analysis of negatively charged pions, all negatively charged tracks have been analyzed. The background from secondary reactions, particle decays, and gamma-conversions has been corrected with the VENUS event generator. The results were also corrected for efficiency and acceptance and the pt spectra were analyzed and extrapolated where necessary to derive the mean yield per rapidity bin dN/dy. The mean multiplicity <pi-> has been derived by summing up the measured dN/dy and extrapolating the rapidity spectrum with a double Gaussian fit to 4pi coverage. The results have been discussed in detail and compared to various model calculations. Microscopical models like URQMD and HSD do not describe the full complexity of Pb+Pb collisions. Especially the production of the positively charged kaons, which carry the major part of strange quarks, cannot be consistently reproduced by the model calculations. Centrality selected minimum bias Pb+Pb collisions can be described as a mixture of a high-density region of multiply colliding nucleons (core) and practically independent nucleon-nucleon collisions (corona). This leads to a smooth evolution from peripheral to central collisions. A more detailed approach derives the ensemble volume from a percolation of elementary clusters. In the percolation model all clusters are formed from coalescing strings that are assumed to decay statistically with the volume dependence of canonical strangeness suppression. The percolation model describes the measured data for top SPS and RHIC energies. At 40A GeV, the system size dependence of the relative strangeness production starts to evolve from the saturation seen at higher energies from peripheral events onwards towards a linear dependence at SIS and AGS. This change of the dependence on system size occurs in the energy region of the observed maximum of the K+ to pi ratio for central Pb+Pb collisions. Future measurements with heavy ion beam energies around this maximum at RHIC and FAIR as well as the upgraded NA49 successor experiment NA61 will further improve our understanding of quark matter and its reflection in modern heavy ion physics and theories.
Starting from the first observation of the halo phenomenon 20 years ago, more and more neutron-rich light nuclei were observed. The study of unstable nuclear systems beyond the dripline is a relatively new branch of nuclear physics. In the present work, the results of an experiment at GSI (Darmstadt) with relativistic beams of the halo nuclei 8He, 11Li and 14Be with energies of 240, 280 and 305 MeV/nucleon, respectively, impinging on a liquid hydrogen target are discussed. Neutron/proton knockout reactions lead to the formation of unbound systems, followed by their immediate decay. The experimental setup, consisting of the neutron detector LAND, the dipole spectrometer ALADIN and different types of tracking detectors, allows the reconstruction of the momentum vectors of all reaction products measured in coincidence. The properties of unbound nuclei are investigated by reconstructing the relative-energy spectra as well as by studying the angular correlations between the reaction products. The observed systems are 9He, 10He, 10Li, 12Li and 13Li. The isotopes 12Li and 13Li are observed for the first time. They are produced in the 1H(14Be, 2pn)12Li and 1H(14Be, 2p)13Li knockout reactions. The obtained relative-energy spectrum of 12Li is described as a single virtual s-state with a scattering length of as = -22;13.7(1.6) fm. The spectrum of 13Li is interpreted as a resonance at an energy of Er = 1.47(13) MeV and a width of Gamma ~ 2 MeV superimposed on a broad correlated background distribution. The isotope 10Li is observed after one-neutron knockout from the halo nucleus 11Li. The obtained relative-energy spectrum is described by a low-lying virtual s-state with a scattering length as = -22.4(4.8) fm and a p-wave resonance with Er = 0.566(14) MeV and Gamma = 0.548(30) MeV, in agreement with previous experiments. The observation of the nucleus 8He in coincidence with one or two neutrons, as a result of proton knockout from 11Li, allows to reconstruct the relative-energy spectra for the heavy helium isotopes, 9He and 10He. The low-energy part of the 9He spectrum is described by a virtual s-state with a scattering length as = -3.16(78) fm. In addition, two resonance states with l 6= 0 at energies of 1.33(8) and 2.4 MeV are observed. For the 10He spectrum, two interpretations are possible. It can be interpreted as a superposition of a narrow resonance at 1.42(10) MeV and a broad correlated background distribution. Alternatively, the spectrum is being well described by two resonances at energies of 1.54(11) and 3.99(26) MeV. Additionally, three-body energy and angular correlations in 10He and 13Li nuclei at the region of the ground state (0 < ECnn < 3 MeV) are studied, providing information about structure of these unbound nuclear systems.
This thesis is devoted to the developement of a classical model for the study of the energetics and stability of carbon nanotubes. The motivation behind such a model stems from the fact that production of nanotubes in a well-controlled manner requires a detailed understanding of their energetics. In order to study this different theoretical approaches are possible, ranging from the computationally expensive quantum mechanical first principle methods to the relatively simple classical models. A wisely developed classical model has the advantage that it could be used for systems of any possible size while still producing reasonable results. The model developed in this thesis is based on the well-known liquid drop model without the volume term and hence we call it liquid surface model. Based on the assumption that the energy of a nanotube can be expressed in terms of its geometrical parameters like surface area, curvature and shape of the edge, liquid surface model is able to predict the binding energy of nanotubes of any chirality once the total energy and the chiral indices of it are known. The model is suggested for open end and capped nanotubes and it is shown that the energy of capped nanotubes is determined by five physical parameters, while for the open end nanotubes three parameters are sufficient. The parameters of the liquid surface model are determined from the calculations performed with the use of empirical Tersoff and Brenner potentials and the accuracy of the model is analysed. It is shown that the liquid surface model can predict the binding energy per atom for capped nanotubes with relative error below 0.3% from that calculated using Brenner potential, corresponding to the absolute energy difference being less than 0.01 eV. The influence of the catalytic nanoparticle on top of which a nanotube grows, on the nanotube energetics is also discussed. It is demonstrated that the presence of catalytic nanoparticle changes the binding energy per atom in such a way that if the interaction of a nanotube with the catalytic nanoparticle is weak then attachment of an additional atom to a nanotube is an energetically favourable process, while if the catalytic nanoparticle nanotube interaction is strong , it becomes energetically more favourable for the nanotube to collapse. The suggested model gives important insights in the energetics and stability of nanotubes of different chiralities and is an important step towards the understanding of nanotube growth process. Young modulus and curvature constant are calculated for single-wall carbon nanotubes from the paremeters of the liquid surface model and demonstrated that the obtained values are in agreement with the values reported earlier both theoretically and experimentally. The calculated Young modulus and the curvature constant were used to conclude about the accuracy of the Tersoff and Brenner potentials. Since the parameters of the liquid surface model are obtained from the Tersoff and Brenner potential calculations, the agreement of elastic properties derived from these parameters corresponds to the fact that both potentials are capable of describing the elastic properties of nanotubes. Finally, the thesis discuss the possible extension of the model to various systems of interest.