F. Csikor scite author profile

Under stress, many crystalline materials exhibit irreversible plastic deformation caused by the motion of lattice dislocations. In plastically deformed microcrystals, internal dislocation avalanches lead to jumps in the stress-strain curves (strain bursts), whereas in macroscopic samples plasticity appears as a smooth process. By combining three-dimensional simulations of the dynamics of interacting dislocations with statistical analysis of the corresponding deformation behavior, we determined the distribution of strain changes during dislocation avalanches and established its dependence on microcrystal size. Our results suggest that for sample dimensions on the micrometer and submicrometer scale, large strain fluctuations may make it difficult to control the resulting shape in a plastic-forming process.

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End Point of the Hot Electroweak Phase Transition

Csikor

Fodor²,

Heitger³

1999

Phys. Rev. Lett.

368

371

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We study the hot electroweak phase transition by four-dimensional lattice simulations and give the phase diagram. A continuum extrapolation is done. We find that the phase transition is first order for Higgs-boson masses m H , 66.5 6 1.4 GeV. Above this end point a rapid crossover occurs. Our result agrees with that of the dimensional reduction approach. It also indicates that the fermionic sector of the standard model (SM) may be included perturbatively. We obtain that the end point in the SM is 72.4 6 1.7 GeV. Thus, the LEP Higgs-boson mass lower bound excludes any electroweak phase transition in the SM. [S0031-9007(98)08047-8] The observed baryon asymmetry is finally determined at the electroweak phase transition (EWPT) [1]. The understanding of this asymmetry needs a quantitative description of the phase transition. Unfortunately, the perturbative approach breaks down for the physically allowed Higgs-boson masses (e.g., m H . 70 GeV) [2]. In order to understand this nonperturbative phenomenon a systematically controllable technique is used, namely, lattice Monte Carlo (MC) simulations. Since merely the bosonic sector is responsible for the bad perturbative features (due to infrared problems) the simulations are done without the inclusion of fermions. The first results dedicated to these questions were obtained on four-dimensional (4D) lattices [3]. Soon after, simulations of the reduced model in three dimensions were initiated as another approach [4]. This technique contains two steps. The first is a perturbative reduction of the original 4D model to a three-dimensional (3D) one by integrating out the heavy degrees of freedom. The second step is the nonperturbative analysis of the 3D model on the lattice, which is less CPU-time consuming than the MC simulation in the 4D model. The comparison of the results obtained by the two techniques is not only a useful cross-check on the perturbative reduction procedure for heavy bosonic modes, but also could give an indication that the fermions, which behave similarly to the heavy bosonic nodes, might be included perturbatively.In the recent years exhaustive studies have been carried out both in the 4D [5] and in the 3D [6] sectors of the problem. These works determined several cosmologically important quantities such as the critical temperature (T c ), interface tension (s), and latent heat (De).Previous works show that the strength of the first order EWPT gets weaker as the mass of the Higgs-boson increases. Actually the line of the first order phase transitions separating the symmetric and Higgs phases on the m H -T c plane has an end point, m H,c . There are several direct and indirect evidences for that. In four dimensions at m H ഠ 80 GeV the EWPT turned out to be extremely weak, even consistent with the no phase transition scenario on the 1.5s level [7]. 3D results show that for m H . 95 GeV no first order phase transition exists [8] and more specifically that the end point is m H,c ഠ 67 GeV [9,10]. In this Letter we present the analysis of the end point on 4D ...

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Pentaquark hadrons from lattice QCD

Csikor¹,

Fodor²,

Katz³

et al. 2003

J. High Energy Phys.

156

187

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We study spin 1/2 isoscalar and isovector candidates in both parity channels for the recently discovered Θ + (1540) pentaquark particle in quenched lattice QCD. Our analysis takes into account all possible uncertainties, such as statistical, finite size and quenching errors when performing the chiral and continuum extrapolations and we have indications that our signal is separated from scattering states. The lowest mass that we find in the I P = 0 − channel is in complete agreement with the experimental value of the Θ + mass. On the other hand, the lowest mass state in the opposite parity I P = 0 + channel is much higher. Our findings suggests that the parity of the Θ + is negative.

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F. Csikor

Spatial correlations and higher-order gradient terms in a continuum description of dislocation dynamics

Dislocation Avalanches, Strain Bursts, and the Problem of Plastic Forming at the Micrometer Scale

End Point of the Hot Electroweak Phase Transition

Pentaquark hadrons from lattice QCD

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