Inscrição na biblioteca: Guest
Portal Digital Begell Biblioteca digital da Begell eBooks Diários Referências e Anais Coleções de pesquisa
Telecommunications and Radio Engineering
SJR: 0.202 SNIP: 0.2 CiteScore™: 0.23

ISSN Imprimir: 0040-2508
ISSN On-line: 1943-6009

Volumes:
Volume 78, 2019 Volume 77, 2018 Volume 76, 2017 Volume 75, 2016 Volume 74, 2015 Volume 73, 2014 Volume 72, 2013 Volume 71, 2012 Volume 70, 2011 Volume 69, 2010 Volume 68, 2009 Volume 67, 2008 Volume 66, 2007 Volume 65, 2006 Volume 64, 2005 Volume 63, 2005 Volume 62, 2004 Volume 61, 2004 Volume 60, 2003 Volume 59, 2003 Volume 58, 2002 Volume 57, 2002 Volume 56, 2001 Volume 55, 2001 Volume 54, 2000 Volume 53, 1999 Volume 52, 1998 Volume 51, 1997

Telecommunications and Radio Engineering

DOI: 10.1615/TelecomRadEng.v54.i4.80
pages 68-79

Nonlinear and Kinetic Effects in the Propagation of an Intense Electromagnetic Pulse Through the Atmosphere

A. I. Golubev
Russian Federal Nuclear Center All-Russian Scientific Research Institute of Experimental Physics, Sarov, 607190, Russia
M. D. Kamchibekov
Russian Federal Nuclear Center All-Russian Scientific Research Institute of Experimental Physics, Sarov, 607190, Russia
A. V. Soldatov
Russian Federal Nuclear Center All-Russian Scientific Research Institute of Experimental Physics, Sarov, 607190, Russia
T. G. Sysoeva
Russian Federal Nuclear Center All-Russian Scientific Research Institute of Experimental Physics, Sarov, 607190, Russia
V. A. Terekhin
Russian Federal Nuclear Center All-Russian Scientific Research Institute of Experimental Physics, Sarov, 607190, Russia
V. T. Tikhonchuk
P.N.Lebedev Physics Institute, Russian Academy of Science, Moscow, 117925, Russia

RESUMO

Kinetic models are derived for the description of intense electromagnetic pulse propagation through the Earth's atmosphere. The first, full model is based on a self-consistent solution to the set of Maxwell's equations coupled with the Boltzmann equation for free electrons in a two-polynomial approximation. The second, reduced model is based on the envelope approximation and is applied to quasi-monochromatic pulses. The capabilities and accuracy of both models are illustrated in several examples. In particular, we discuss the evolution of the pulse shape due to its absorption in the atmosphere and the evolution of the electron distribution function.


Articles with similar content:

TEMPORAL ANALYSIS OF REFLECTED OPTICAL SIGNALS FOR SHORT PULSE LASER INTERACTION WITH NONHOMOGENEOUS TISSUE PHANTOMS
ICHMT DIGITAL LIBRARY ONLINE, Vol.16, 2004, issue
Ashish Trivedi, Kunal Mitra
Study of the Instability of Wave Packets in Fluidized-Bed Furnaces within the Framework of Ginzburg–Landau Equation
Heat Transfer Research, Vol.34, 2003, issue 1&2
E. V. Toropov, G. F. Kuznetsov, I. V. Elyukhina
PECULIARITIES OF DOUBLE FREQUENCY RADAR FOR POLYDISPERSE AEROSOLS SOUNDING
Telecommunications and Radio Engineering, Vol.70, 2011, issue 2
G. I. Khlopov, R. Knoechel, K. Schuenemann, A. M. Linkova, A. L Teplyuk, O. A. Voitovych
Modeling Ionic Continua Under Multifield Conditions
International Journal for Multiscale Computational Engineering, Vol.4, 2006, issue 2
John G. Michopoulos
SEQUENTIAL NANO-PATTERNING USING ELECTRON AND LASER BEAMS: A NUMERICAL METHODOLOGY
ICHMT DIGITAL LIBRARY ONLINE, Vol.16, 2004, issue
R. Ryan Vallance, Basil T. Wong, M. Pinar Menguc