Strongly coupled large-angle stimulated Raman scattering of short laser pulse in plasma-filled capillary
Strongly coupled large-angle stimulated Raman scattering (LA SRS) of a short intense laser pulse develops in a plane plasma-filled capillary differently than in a plasma with open boundaries. Coupling...
Strongly coupled large-angle stimulated Raman scattering (LA SRS) of a short intense laser pulse develops in a plane plasma-filled capillary differently than in a plasma with open boundaries. Coupling...
Electron acceleration by a circularly polarized laser pulse in the presence of an obliquely incident magnetic field in vacuum
Laser-induced acceleration of an electron injected initially at an angle to the direction of a circularly polarized laser pulse in the presence of an obliquely incident magnetic field has been investi...
Laser-induced acceleration of an electron injected initially at an angle to the direction of a circularly polarized laser pulse in the presence of an obliquely incident magnetic field has been investi...
Effect of emission velocity spread of secondary electrons in two-sided multipactor
Phys. Plasmas 12, 053102 (2005); doi:10.1063/1.1881532
Published 7 April 2005
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Detailed numerical simulations of the two-sided multipactor have been carried out within a plane-parallel model. The main aim of the simulations is to clarify the uncertainty that still exists in the literature concerning the overlapping of multipactor zones. Three different codes (Monte Carlo, particle-in-cell, and statistical) were used to calculate the multipactor charts within a wide range of parameters such as spread of initial velocities of the secondary electrons and maximum value of the secondary emission yield. It was found that an increase in the spread of initial velocities results in overlapping of the multipactor zones, provided the secondary emission is high enough. In the opposite case, an increase in the spread of initial velocities leads to a suppression of the higher multipactor zones.
©2005 American Institute of Physics
| History: | Received 22 October 2004; accepted 1 February 2005; published 7 April 2005 |
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