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Within the ADD-model, we elaborate an idea by Vacavant and Hinchliffe [J. Phys. G 27 (2001) 1839] and show quantitatively how to determine the fundamental scale of TeV-gravity and the number of compactified extra dimensions from data at LHC. We demonstrate that the ADD-model leads to strong correlations between the missing ET in gravitons at different center of mass energies. This correlation puts strong constraints on this model for extra dimensions, if probed at s=5.5 TeV and s=14 TeV at LHC.
The kaon nuclear optical potential is studied including the effect of the Θ+ pentaquark. The one-nucleon contribution is obtained using an extension of the Jülich meson-exchange potential as bare kaon–nucleon interaction. Significant differences between a fully self-consistent calculation and the usually employed low-density Tρ approach are observed. The influence of the one-nucleon absorption process, KN→Θ+, on the kaon optical potential is negligible due to the small width of the pentaquark. In contrast, the two-nucleon mechanism, KNN→Θ+N, estimated from the coupling of the pentaquark to a two-meson cloud, provides the required amount of additional kaon absorption to reconcile with data the systematically low K+-nucleus reaction cross sections found by the theoretical models.
We solve the coupled Wong Yang–Mills equations for both U(1) and SU(2) gauge groups and anisotropic particle momentum distributions numerically on a lattice. For weak fields with initial energy density much smaller than that of the particles we confirm the existence of plasma instabilities and of exponential growth of the fields which has been discussed previously. Also, the SU(2) case is qualitatively similar to U(1), and we do find significant “abelianization” of the non-Abelian fields during the period of exponential growth. However, the effect nearly disappears when the fields are strong. This is because of the very rapid isotropization of the particle momenta by deflection in a strong field on time scales comparable to that for the development of Yang–Mills instabilities. This mechanism for isotropization may lead to smaller entropy increase than collisions and multiplication of hard gluons, which is interesting for the phenomenology of high-energy heavy-ion collisions.
Large extra dimensions could lower the Planck scale to experimentally accessible values. Not only is the Planck scale the energy scale at which effects of modified gravity become important. The Planck length also acts as a minimal length in nature, providing a natural ultraviolet cutoff and a limit to the possible resolution of spacetime.
In this Letter we examine the influence of the minimal length on the Casimir energy between two plates.
In vorliegender Arbeit wurde ein Modell zur Beschreibung des chiralen Phasen Übergangs eines mesonischen Mediums im Gleichgewicht als effektiver Manifestation des Übergangs von hadronischer Materie zum Quark-Gluon-Plasma präsentiert, und im Rahmen eines selbstkonsistenten Vielteilchenresummationsverfahrens in Doppelblasennäherung numerisch gelöst.
I review recent developments in determining the QCD phase diagram by means of lattice simulations.
Since the invention of methods to side-step the sign problem a few years ago, a number
of additional variants have been proposed, and progress has been made towards understanding
some of the systematics involved. All available techniques agree on the transition temperature
as a function of density in the regime mq/T <~1. There are by now four calculations with signals
for a critical point, two of them at similar parameter values and with consistent results. However,
it also emerges that the location of the critical point is exceedingly quark mass sensitive. At the
same time sizeable finite volume, cut-off and step size effects have been uncovered, demanding
additional investigations with exact algorithms on larger and finer lattices before quantitative conclusions
can be drawn. Depending on the sign of these corrections, there is ample room for the
eventual phase diagram to look as expected or also quite different, with no critical point at all.
We present a numerical technique for calculating path integrals in non-compact U(1) and SU(2) gauge theories. The gauge fields are represented by a superposition of pseudoparticles of various types with their amplitudes and color orientations as degrees of freedom. Applied to Maxwell theory this technique results in a potential which is in excellent agreement with the Coulomb potential. For SU(2) Yang-Mills theory the same technique yields clear evidence of confinement. Varying the coupling constant exhibits the same scaling behavior for the string tension, the topological susceptibility and the critical temperature while their dimensionless ratios are similar to those obtained in lattice calculations.
This thesis is devoted to the study of Micro Structured Electrode (MSE) sustained discharges. Innovative approaches in this work are i) the implementation of MSE arrays for high-pressure plasma generation and ii) the use of diode laser atomic absorption spectroscopy for investigating sub-millimetric discharges. By means of MSE arrays the discharge gap is scaled down to the sub-millimetric range and accordingly the working pressure could be increased up to atmospheric. It should be underlined that besides the ease of use, since expensive vacuum equipment is not required, high-pressure discharges offer also a high density of active species. A MSE consists of holes, regularly distributed in a composite sheet made of two metal layers separated by an insulator. The electrodes and insulator thickness and the diameter of the holes are in the 100 micrometer range. Based on these microstructures stable non-filamentary DC discharges are generated in noble gases and gas mixtures at pressures up to 1000 mbar. The MSE sustained discharge can be considered as a normal glow discharge whereby the excitation and ionization efficiency is increased by the specific electrode configuration (hollow cathode geometry). Large area high-pressure plasma can be achieved by parallel operation of a large number of microdischarges. Parallel operation of up to 200 microdischarges without individual ballast was proven for pressures up to 300 mbar. Furthermore, arrays of resistively decoupled microdischarges were operated up to atmospheric pressure. Spectral investigations have revealed the presence of highly energetic electrons (20 eV), a large density of atoms in metastable states (1013 cm-3) and a high electron density (1015 cm-3). Although the plasma confined inside the hole of the MSE may reach gas temperatures up to 1000 K, the ambient gas temperature immediately above the microstructure exceeds only slightly the room temperature. The reactivity of the MSE sustained discharge was demonstrated in respect to waste gas decomposition and surface treatment. The MSE arrays are providing a non-equilibrium high-pressure plasma, which is very promising for surface processing, plasma chemistry and generation of UV radiation.
The recently proposed baryon-strangeness correlation (C_BS) is studied with a string-hadronic transport model (UrQMD) for various energies from E_lab=4 AGeV to \sqrt s=200 AGeV. It is shown that rescattering among secondaries can not mimic the predicted correlation pattern expected for a Quark-Gluon-Plasma. However, we find a strong increase of the C_BS correlation function with decreasing collision energy both for pp and Au+Au/Pb+Pb reactions. For Au+Au reactions at the top RHIC energy (\sqrt s=200 AGeV), the C_BS correlation is constant for all centralities and compatible with the pp result. With increasing width of the rapidity window, C_BS follows roughly the shape of the baryon rapidity distribution. We suggest to study the energy and centrality dependence of C_BS which allow to gain information on the onset of the deconfinement transition in temperature and volume.