44 research outputs found
Analytic solutions for the one-dimensional compressible Euler equation with heat conduction closed with different kind of equation of states
We present analytic self-similar or traveling wave solutions for a
one-dimensional coupled system of continuity, compressible Euler and heat
conduction equations. Different kind of equation of states are investigated. In
certain forms of the equation of state one can arrive to a picture regarding
the long time behavior of density and pressure. The impact of these quantities
on the evolution of temperature is also discussed.Comment: 3 figures, will be submitted to Physics of Fluid
Laser induced distortion of band structure in solids: an analytic model
We consider a spatially periodic (cosine) potential as a model for a
crystalline solid that interacts with a harmonically oscillating external
electric field. This problem is periodic both in space and time and can be
solved analytically using the Kramers-Henneberger co-moving frame. By analyzing
the stability of the closely related Mathieu-type differential equation, the
electronic band structure can be obtained. We demonstrate that by changing the
field intensity, the width of the zero-field band gaps can be drastically
modified, including the special case when the external field causes the band
gaps to disappearComment: 8 pages, 3 figure
Interaction of antiproton with helium based on ab-initio calculations
We present ionization cross sections for antiproton and helium collisions
based on ab-initio time-dependent coupled channel method. In our calculations a
finite basis set of regular helium Coulomb wave packets and Slater function
were used. The semiclassical approximation was applied with the time-dependent
Coulomb potential to describe the antiproton electron interaction. Three
different projectile energies were considered as 10, 50 and 100 keV. We found
clear evidence for the formation of the anti-cusp in the differential
distributions.Comment: 17 pages and 3*3 figure
Electron Acceleration in Underdense Plasmas Described with a Classical Effective Theory
An effective theory of laser--plasma based particle acceleration is
presented. Here we treated the plasma as a continuous medium with an index of
refraction in which a single electron propagates. Because of the
simplicity of this model, we did not need to perform PIC simulations in order
to study the properties of the electron acceleration. We studied the properties
of the electron motion due to the Lorentz force and the relativistic equations
of motion were numerically solved and analysed. We compared our results to PIC
simulations and experimental data.
Keywords: Underdense plasma; Electron acceleration; Classical
electrodynamics; Relativistic equation of motion; Ultrashort laser pulsesComment: 14 pages, 7 figures. Proceedings to the ECLIM 2014 Conference
(Paris). Submitted to Laser and Particle Beams (Cambridge Journals