Radiation reaction effects in relativistic plasmas
ORAL
Abstract
In the past decades, there has been a steady increase in interest in intense field plasma physics.
This has been motivated by the fast technological development of the laser facilities. Both classical
and quantum radiation reaction effects on the dynamics of plasma are of interest. In DI Piazza Phys.Rev.Lett 054802, one found
that the quantum radiation reaction mechanism leads to a heating effect in the background plasma. In the case of the classical radiation reaction, it is found in Naseri Phys.Rev.E 107 054802 that the temperature of the background plasma drops.
In Naseri Phys.Rev.E 107 054802, the evolution of electrostatic plasma waves has been studied, using the relativistic Vlasov equation
extended by the Landau-Lifshitz radiation reaction. Here, the model includes the
back-reaction effect due to the emission of single-particle Larmor radiation. In particular, the Langmuir
wave damping is calculated as a function of wavenumber, initial temperature, and initial electric field
amplitude. Moreover, the background distribution function loses energy in the process, and the cooling
rate as a function of initial temperature and initial wave amplitude were calculated.
Finally, it is found that the relative contribution to the energy loss associated with background
cooling decreases slowly with the initial wave amplitude. A further study to find the transition regime
from classical to quantum radiation reactions is planned.
This has been motivated by the fast technological development of the laser facilities. Both classical
and quantum radiation reaction effects on the dynamics of plasma are of interest. In DI Piazza Phys.Rev.Lett 054802, one found
that the quantum radiation reaction mechanism leads to a heating effect in the background plasma. In the case of the classical radiation reaction, it is found in Naseri Phys.Rev.E 107 054802 that the temperature of the background plasma drops.
In Naseri Phys.Rev.E 107 054802, the evolution of electrostatic plasma waves has been studied, using the relativistic Vlasov equation
extended by the Landau-Lifshitz radiation reaction. Here, the model includes the
back-reaction effect due to the emission of single-particle Larmor radiation. In particular, the Langmuir
wave damping is calculated as a function of wavenumber, initial temperature, and initial electric field
amplitude. Moreover, the background distribution function loses energy in the process, and the cooling
rate as a function of initial temperature and initial wave amplitude were calculated.
Finally, it is found that the relative contribution to the energy loss associated with background
cooling decreases slowly with the initial wave amplitude. A further study to find the transition regime
from classical to quantum radiation reactions is planned.
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Publication: 1- H. Al-Naseri and G. Brodin, Radiation reaction effects in relativistic plasmas: The electrostatic<br>limit. Physical Review E, 107(3), 035203 (2023).<br><br>2- H., Al-Naseri and G., Brodin, "Transition from classical to quantum radiation reaction in relativistic<br>plasma", under progress.
Presenters
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Haidar Al-Naseri
DEPARTMENT OF PHYSICS, UMEÅ UNIVERSITY
Authors
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Haidar Al-Naseri
DEPARTMENT OF PHYSICS, UMEÅ UNIVERSITY
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Gert Brodin
DEPARTMENT OF PHYSICS, UMEÅ UNIVERSITY