Experiments Designed to Study the Non-Linear Transition of High-Power Microwaves through Plasmas and Gases

Yakov E. Krasik; John G. Leopold; Guy Shafir; Yang Cao; Yuri P. Bliokh; Vladislav V. Rostov; Valery Godyak; Meytal Siman-Tov; Raanan Gad; Amnon Fisher; Vladimir Bernshtam; Svetlana Gleizer; Denis Zolotukhin; Yakov Slutsker

doi:10.3390/plasma2010006

Experiments Designed to Study the Non-Linear Transition of High-Power Microwaves through Plasmas and Gases

Yakov E. Krasik^*, John G. Leopold, Guy Shafir, Yang Cao, Yuri P. Bliokh, Vladislav V. Rostov, Valery Godyak, Meytal Siman-Tov, Raanan Gad, Amnon Fisher, Vladimir Bernshtam, Svetlana Gleizer, Denis Zolotukhin, Yakov Slutsker

^*Corresponding author for this work

Department of Particle Physics and Astrophysics

Research output: Contribution to journal › Review article › peer-review

4 Citations (Scopus)

Abstract

The interaction of powerful sub-picosecond timescale lasers with neutral gas and plasmas has stimulated enormous interest because of the potential to accelerate particles to extremely large energies by the intense wakefields formed and without being limited by high accelerating gradients as in conventional accelerator cells. The interaction of extremely high-power electromagnetic waves with plasmas is though, of general interest and also to plasma heating and wake-field formation. The study of this subject has become more accessible with the availability of sub-nanosecond timescale GigaWatt (GW) power scale microwave sources. The interaction of such high-power microwaves (HPM) with under-dense plasmas is a scale down of the picosecond laser—dense plasma interaction situation. We present a review of a unique experiment in which such interactions are being studied, some of our results so far including results of our numerical modeling. Such experiments have not been performed before, self-channeling of HPM through gas and plasma and extremely fast plasma electron heating to keV energies have already been observed, wakefields resulting from the transition of HPM through plasma are next and more is expected to be revealed.

Original language	English
Pages (from-to)	51-64
Number of pages	14
Journal	Plasma
Volume	2
Issue number	1
DOIs	https://doi.org/10.3390/plasma2010006
Publication status	Published - 8 Mar 2019

Funding

This work was funded in part by the PAZY under Grant No. 2020960 and in part by the research program of the RAS #10.

All Science Journal Classification (ASJC) codes

Engineering (miscellaneous)
Materials Science (miscellaneous)
Physics and Astronomy (miscellaneous)

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10.3390/plasma2010006Licence: CC BY

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@article{85dde1ec6b314829bbb5a452470797a1,

title = "Experiments Designed to Study the Non-Linear Transition of High-Power Microwaves through Plasmas and Gases",

abstract = "The interaction of powerful sub-picosecond timescale lasers with neutral gas and plasmas has stimulated enormous interest because of the potential to accelerate particles to extremely large energies by the intense wakefields formed and without being limited by high accelerating gradients as in conventional accelerator cells. The interaction of extremely high-power electromagnetic waves with plasmas is though, of general interest and also to plasma heating and wake-field formation. The study of this subject has become more accessible with the availability of sub-nanosecond timescale GigaWatt (GW) power scale microwave sources. The interaction of such high-power microwaves (HPM) with under-dense plasmas is a scale down of the picosecond laser—dense plasma interaction situation. We present a review of a unique experiment in which such interactions are being studied, some of our results so far including results of our numerical modeling. Such experiments have not been performed before, self-channeling of HPM through gas and plasma and extremely fast plasma electron heating to keV energies have already been observed, wakefields resulting from the transition of HPM through plasma are next and more is expected to be revealed.",

author = "Krasik, \{Yakov E.\} and Leopold, \{John G.\} and Guy Shafir and Yang Cao and Bliokh, \{Yuri P.\} and Rostov, \{Vladislav V.\} and Valery Godyak and Meytal Siman-Tov and Raanan Gad and Amnon Fisher and Vladimir Bernshtam and Svetlana Gleizer and Denis Zolotukhin and Yakov Slutsker",

year = "2019",

month = mar,

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doi = "10.3390/plasma2010006",

language = "English",

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journal = "Plasma",

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T1 - Experiments Designed to Study the Non-Linear Transition of High-Power Microwaves through Plasmas and Gases

AU - Krasik, Yakov E.

AU - Leopold, John G.

AU - Shafir, Guy

AU - Cao, Yang

AU - Bliokh, Yuri P.

AU - Rostov, Vladislav V.

AU - Godyak, Valery

AU - Siman-Tov, Meytal

AU - Gad, Raanan

AU - Fisher, Amnon

AU - Bernshtam, Vladimir

AU - Gleizer, Svetlana

AU - Zolotukhin, Denis

AU - Slutsker, Yakov

PY - 2019/3/8

Y1 - 2019/3/8

N2 - The interaction of powerful sub-picosecond timescale lasers with neutral gas and plasmas has stimulated enormous interest because of the potential to accelerate particles to extremely large energies by the intense wakefields formed and without being limited by high accelerating gradients as in conventional accelerator cells. The interaction of extremely high-power electromagnetic waves with plasmas is though, of general interest and also to plasma heating and wake-field formation. The study of this subject has become more accessible with the availability of sub-nanosecond timescale GigaWatt (GW) power scale microwave sources. The interaction of such high-power microwaves (HPM) with under-dense plasmas is a scale down of the picosecond laser—dense plasma interaction situation. We present a review of a unique experiment in which such interactions are being studied, some of our results so far including results of our numerical modeling. Such experiments have not been performed before, self-channeling of HPM through gas and plasma and extremely fast plasma electron heating to keV energies have already been observed, wakefields resulting from the transition of HPM through plasma are next and more is expected to be revealed.

AB - The interaction of powerful sub-picosecond timescale lasers with neutral gas and plasmas has stimulated enormous interest because of the potential to accelerate particles to extremely large energies by the intense wakefields formed and without being limited by high accelerating gradients as in conventional accelerator cells. The interaction of extremely high-power electromagnetic waves with plasmas is though, of general interest and also to plasma heating and wake-field formation. The study of this subject has become more accessible with the availability of sub-nanosecond timescale GigaWatt (GW) power scale microwave sources. The interaction of such high-power microwaves (HPM) with under-dense plasmas is a scale down of the picosecond laser—dense plasma interaction situation. We present a review of a unique experiment in which such interactions are being studied, some of our results so far including results of our numerical modeling. Such experiments have not been performed before, self-channeling of HPM through gas and plasma and extremely fast plasma electron heating to keV energies have already been observed, wakefields resulting from the transition of HPM through plasma are next and more is expected to be revealed.

UR - https://www.scopus.com/pages/publications/85081201788

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DO - 10.3390/plasma2010006

M3 - Review article

AN - SCOPUS:85081201788

SN - 2571-6182

VL - 2

SP - 51

EP - 64

JO - Plasma

JF - Plasma

IS - 1

ER -

Experiments Designed to Study the Non-Linear Transition of High-Power Microwaves through Plasmas and Gases

Abstract

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