Electromagnetic energy penetration in the self-induced transparency
  regime of relativistic laser-plasma interactions

A. B. Borisov; A. I. Akhiezer; A. Kim; A. Kim; A. Pukhov; B. F. Lasinski; C. Max; C. S. Lai; D. Anderson; E. Lefebvre; F. Cattani; F. Cattani; F. Cattani; F. S. Felber; G. Z. Sun; H. Ruhl; H. Sakagami; J. C. Adam; J. Fuchs; J. H. Marburger; J. Mason; M. Lisak; M. Tabak; M. Tatarakis; M. Tushentsov; P. K. Kaw; P. Kaw; S. C. Wilks; S. C. Wilks; S. Guerin; S. V. Bulanov; V. A. Kozlov; X. L. Chen; Y. Sentoku

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Electromagnetic energy penetration in the self-induced transparency regime of relativistic laser-plasma interactions

Authors: A. B. Borisov
A. I. Akhiezer
A. Kim
A. Kim
A. Pukhov
B. F. Lasinski
C. Max
C. S. Lai
D. Anderson
E. Lefebvre
F. Cattani
F. Cattani
F. Cattani
F. S. Felber
G. Z. Sun
H. Ruhl
H. Sakagami
J. C. Adam
J. Fuchs
J. H. Marburger
J. Mason
M. Lisak
M. Tabak
M. Tatarakis
M. Tushentsov
P. K. Kaw
P. Kaw
S. C. Wilks
S. C. Wilks
S. Guerin
S. V. Bulanov
V. A. Kozlov
X. L. Chen
Y. Sentoku
Publication date: 24 October 2000
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Two scenarios for the penetration of relativistically intense laser radiation into an overdense plasma, accessible by self-induced transparency, are presented. For supercritical densities less than 1.5 times the critical one, penetration of laser energy occurs by soliton-like structures moving into the plasma. At higher background densities laser light penetrates over a finite length only, that increases with the incident intensity. In this regime plasma-field structures represent alternating electron layers separated by about half a wavelength by depleted regions.Comment: 9 pages, 4 figures, submitted for publication to PR

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