Dynamical Schwinger effect and high-intensity lasers. Realising nonperturbative QED

We consider the possibility of experimental verification of vacuum e + e - pair creation at the focus of two counter-propagating optical laser beams with intensities 10 20 –10 , achievable with present-day petawatt lasers, and approaching the Schwinger limit: 10 to be reached at ELI. Our approach is...

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Veröffentlicht in:Eur. Phys. J. D 2009-11, Vol.55 (2), p.341-358
Hauptverfasser: Blaschke, D. B., Prozorkevich, A. V., Röpke, G., Roberts, C. D., Schmidt, S. M., Shkirmanov, D. S., Smolyansky, S. A.
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Sprache:eng
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Zusammenfassung:We consider the possibility of experimental verification of vacuum e + e - pair creation at the focus of two counter-propagating optical laser beams with intensities 10 20 –10 , achievable with present-day petawatt lasers, and approaching the Schwinger limit: 10 to be reached at ELI. Our approach is based on the collisionless kinetic equation for the evolution of the e + and e - distribution functions governed by a non-Markovian source term for pair production. As possible experimental signals of vacuum pair production we consider e + e - annihilation into γ-pairs and the refraction of a high-frequency probe laser beam by the produced e + e - plasma. We discuss the dependence of the dynamical pair production process on laser wavelength, with special emphasis on applications in the X-ray domain (X-FEL), as well as the prospects for μ + μ - and π + π - pair creation at high-intensity lasers. We investigate perspectives for using high-intensity lasers as “boosters” of ion beams in the few-GeV per nucleon range, which is relevant, e.g., to the exploration of the QCD phase transition in laboratory experiments.
ISSN:1434-6060
1434-6079
DOI:10.1140/epjd/e2009-00156-y