Laser-Plasma Interaction Experiment for Solar Burst Studies

J. R. Marquès; C. Briand; F. Amiranoff; S. Depierreux; M. Grech; L. Lancia; F. Pérez; A. Sgattoni; T. Vinci; C. Riconda

doi:10.1103/PhysRevLett.124.135001

Laser-Plasma Interaction Experiment for Solar Burst Studies

J. R. Marquès
, C. Briand
, F. Amiranoff
, S. Depierreux
, M. Grech
, L. Lancia
, F. Pérez
, A. Sgattoni
, T. Vinci
, C. Riconda

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Résumé

A new experimental platform based on laser-plasma interaction is proposed to explore the fundamental processes of wave coupling at the origin of interplanetary radio emissions. It is applied to the study of electromagnetic (EM) emission at twice the plasma frequency (2ωp) observed during solar bursts and thought to result from the coalescence of two Langmuir waves (LWs). In the interplanetary medium, the first LW is excited by electron beams, while the second is generated by electrostatic decay of Langmuir waves. In the present experiment, instead of an electron beam, an energetic laser propagating through a plasma excites the primary LW, with characteristics close to those at near-Earth orbit. The EM radiation at 2ωp is observed at different angles. Its intensity, spectral evolution, and polarization confirm the LW-coalescence scenario.

langue originale	Anglais
Numéro d'article	135001
journal	Physical Review Letters
Volume	124
Numéro de publication	13
Les DOIs	https://doi.org/10.1103/PhysRevLett.124.135001
état	Publié - 3 avr. 2020

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10.1103/PhysRevLett.124.135001

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title = "Laser-Plasma Interaction Experiment for Solar Burst Studies",

abstract = "A new experimental platform based on laser-plasma interaction is proposed to explore the fundamental processes of wave coupling at the origin of interplanetary radio emissions. It is applied to the study of electromagnetic (EM) emission at twice the plasma frequency (2ωp) observed during solar bursts and thought to result from the coalescence of two Langmuir waves (LWs). In the interplanetary medium, the first LW is excited by electron beams, while the second is generated by electrostatic decay of Langmuir waves. In the present experiment, instead of an electron beam, an energetic laser propagating through a plasma excites the primary LW, with characteristics close to those at near-Earth orbit. The EM radiation at 2ωp is observed at different angles. Its intensity, spectral evolution, and polarization confirm the LW-coalescence scenario.",

author = "Marqu{\`e}s, \{J. R.\} and C. Briand and F. Amiranoff and S. Depierreux and M. Grech and L. Lancia and F. P{\'e}rez and A. Sgattoni and T. Vinci and C. Riconda",

note = "Publisher Copyright: {\textcopyright} 2020 American Physical Society.",

year = "2020",

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doi = "10.1103/PhysRevLett.124.135001",

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AU - Marquès, J. R.

AU - Briand, C.

AU - Amiranoff, F.

AU - Depierreux, S.

AU - Grech, M.

AU - Lancia, L.

AU - Pérez, F.

AU - Sgattoni, A.

AU - Vinci, T.

AU - Riconda, C.

PY - 2020/4/3

Y1 - 2020/4/3

N2 - A new experimental platform based on laser-plasma interaction is proposed to explore the fundamental processes of wave coupling at the origin of interplanetary radio emissions. It is applied to the study of electromagnetic (EM) emission at twice the plasma frequency (2ωp) observed during solar bursts and thought to result from the coalescence of two Langmuir waves (LWs). In the interplanetary medium, the first LW is excited by electron beams, while the second is generated by electrostatic decay of Langmuir waves. In the present experiment, instead of an electron beam, an energetic laser propagating through a plasma excites the primary LW, with characteristics close to those at near-Earth orbit. The EM radiation at 2ωp is observed at different angles. Its intensity, spectral evolution, and polarization confirm the LW-coalescence scenario.

AB - A new experimental platform based on laser-plasma interaction is proposed to explore the fundamental processes of wave coupling at the origin of interplanetary radio emissions. It is applied to the study of electromagnetic (EM) emission at twice the plasma frequency (2ωp) observed during solar bursts and thought to result from the coalescence of two Langmuir waves (LWs). In the interplanetary medium, the first LW is excited by electron beams, while the second is generated by electrostatic decay of Langmuir waves. In the present experiment, instead of an electron beam, an energetic laser propagating through a plasma excites the primary LW, with characteristics close to those at near-Earth orbit. The EM radiation at 2ωp is observed at different angles. Its intensity, spectral evolution, and polarization confirm the LW-coalescence scenario.

UR - https://www.scopus.com/pages/publications/85083755278

U2 - 10.1103/PhysRevLett.124.135001

DO - 10.1103/PhysRevLett.124.135001

M3 - Article

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AN - SCOPUS:85083755278

SN - 0031-9007

VL - 124

JO - Physical Review Letters

JF - Physical Review Letters

IS - 13

M1 - 135001

ER -

Laser-Plasma Interaction Experiment for Solar Burst Studies

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