Cooling of relativistic electron beams in chirped laser pulses

The next few years will see next-generation high-power laser facilities (such as the Extreme Light Infrastructure) become operational, for which it is important to understand how interaction with intense laser pulses affects the bulk properties of a relativistic electron beam. At such high field int...

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Bibliographic Details
Published in:arXiv.org 2015-05
Main Authors: Yoffe, Samuel R, Noble, Adam, Kravets, Yevgen, Jaroszynski, Dino A
Format: Article
Language:English
Subjects:
Cooling
Cooling effects
Energy distribution
High power lasers
Laser beams
Laser cooling
Lasers
Predictions
Pulse propagation
Pulse shape
Relativism
Relativistic effects
Relativistic electron beams
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Summary:The next few years will see next-generation high-power laser facilities (such as the Extreme Light Infrastructure) become operational, for which it is important to understand how interaction with intense laser pulses affects the bulk properties of a relativistic electron beam. At such high field intensities, we expect both radiation reaction and quantum effects to play a significant role in the beam dynamics. The resulting reduction in relative energy spread (beam cooling) at the expense of mean beam energy predicted by classical theories of radiation reaction depends only on the energy of the laser pulse. Quantum effects suppress this cooling, with the dynamics additionally sensitive to the distribution of energy within the pulse. Since chirps occur in both the production of high-intensity pulses (CPA) and the propagation of pulses in media, the effect of using chirps to modify the pulse shape has been investigated using a semi-classical extension to the Landau--Lifshitz theory. Results indicate that even large chirps introduce a significantly smaller change to final state predictions than going from a classical to quantum model for radiation reaction, the nature of which can be intuitively understood.
ISSN:2331-8422
DOI:10.48550/arxiv.1505.04691