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Vranic, M., Grismayer, T., Fonseca, R. A. & Silva, L. O. (2016). Quantum radiation reaction in head-on laser-electron beam interaction. New Journal of Physics. 18 (7)

Exportar Referência (IEEE)

M. Vranic et al.,  "Quantum radiation reaction in head-on laser-electron beam interaction", in New Journal of Physics, vol. 18, no. 7, 2016

Exportar BibTeX

@article{vranic2016_1715017971340,
	author = "Vranic, M. and Grismayer, T. and Fonseca, R. A. and Silva, L. O.",
	title = "Quantum radiation reaction in head-on laser-electron beam interaction",
	journal = "New Journal of Physics",
	year = "2016",
	volume = "18",
	number = "7",
	doi = "10.1088/1367-2630/18/7/073035",
	url = "http://iopscience.iop.org/article/10.1088/1367-2630/18/7/073035"
}

Exportar RIS

TY - JOUR
TI - Quantum radiation reaction in head-on laser-electron beam interaction
T2 - New Journal of Physics
VL - 18
IS - 7
AU - Vranic, M.
AU - Grismayer, T.
AU - Fonseca, R. A.
AU - Silva, L. O.
PY - 2016
SN - 1367-2630
DO - 10.1088/1367-2630/18/7/073035
UR - http://iopscience.iop.org/article/10.1088/1367-2630/18/7/073035
AB - In this paper, we investigate the evolution of the energy spread and the divergence of electron beams while they interact with different laser pulses at intensities where quantum effects and radiation reaction are of relevance. The interaction is modelled with a quantum electrodynamic (QED)-PIC code and the results are compared with those obtained using a standard PIC code with a classical radiation reaction module. In addition, an analytical model is presented that estimates the value of the final electron energy spread after the interaction with the laser has finished. While classical radiation reaction is a continuous process, in QED, radiation emission is stochastic. The two pictures reconcile in the limit when the emitted photons energy is small compared to the energy of the emitting electrons. The energy spread of the electron distribution function always tends to decrease with classical radiation reaction, whereas the stochastic QED emission can also enlarge it. These two tendencies compete in the QED-dominated regime. Our analysis, supported by the QED module, reveals an upper limit to the maximal attainable energy spread due to stochasticity that depends on laser intensity and the electron beam average energy. Beyond this limit, the energy spread decreases. These findings are verified for different laser pulse lengths ranging from short similar to 30 fs pulses presently available to the long similar to 150 fs pulses expected in the near-future laser facilities, and compared with a theoretical model. Our results also show that near future experiments will be able to probe this transition and to demonstrate the competition between enhanced QED induced energy spread and energy spectrum narrowing from classical radiation reaction.
ER -