Plasma Collision in a Gas Atmosphere

S. Le Pape; L. Divol; G. Huser; J. Katz; A. Kemp; J. S. Ross; R. Wallace; S. Wilks

doi:10.1103/PhysRevLett.124.025003

Plasma Collision in a Gas Atmosphere

S. Le Pape
, L. Divol
, G. Huser
, J. Katz
, A. Kemp
, J. S. Ross
, R. Wallace
, S. Wilks

Research output: Contribution to journal › Article › peer-review

Abstract

We present a study on the impact of a gas atmosphere on the collision of two counterpropagating plasmas (gold and carbon). Imaging optical Thomson scattering data of the plasma collision with and without helium in between have been obtained at the Omega laser facility. Without gas, we observed large scale mixing of colliding gold and carbon ions. Once ambient helium is added, the two plasmas remain separated. The difference in ionic temperature is consistent with a reduction of the maximum Mach number of the flow from M=7 to M=4. It results in a reduction of a factor ∼10 of the counterstreaming ion-ion mean free path. By adding a low-density ambient gas, it is possible to control the collision of two high-velocity counterstreaming plasma, transitioning from an interpenetrating regime to a regime in agreement with a hydrodynamic description.

Original language	English
Article number	025003
Journal	Physical Review Letters
Volume	124
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevLett.124.025003
Publication status	Published - 15 Jan 2020
Externally published	Yes

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10.1103/PhysRevLett.124.025003

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title = "Plasma Collision in a Gas Atmosphere",

abstract = "We present a study on the impact of a gas atmosphere on the collision of two counterpropagating plasmas (gold and carbon). Imaging optical Thomson scattering data of the plasma collision with and without helium in between have been obtained at the Omega laser facility. Without gas, we observed large scale mixing of colliding gold and carbon ions. Once ambient helium is added, the two plasmas remain separated. The difference in ionic temperature is consistent with a reduction of the maximum Mach number of the flow from M=7 to M=4. It results in a reduction of a factor ∼10 of the counterstreaming ion-ion mean free path. By adding a low-density ambient gas, it is possible to control the collision of two high-velocity counterstreaming plasma, transitioning from an interpenetrating regime to a regime in agreement with a hydrodynamic description.",

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T1 - Plasma Collision in a Gas Atmosphere

AU - Le Pape, S.

AU - Divol, L.

AU - Huser, G.

AU - Katz, J.

AU - Kemp, A.

AU - Ross, J. S.

AU - Wallace, R.

AU - Wilks, S.

PY - 2020/1/15

Y1 - 2020/1/15

N2 - We present a study on the impact of a gas atmosphere on the collision of two counterpropagating plasmas (gold and carbon). Imaging optical Thomson scattering data of the plasma collision with and without helium in between have been obtained at the Omega laser facility. Without gas, we observed large scale mixing of colliding gold and carbon ions. Once ambient helium is added, the two plasmas remain separated. The difference in ionic temperature is consistent with a reduction of the maximum Mach number of the flow from M=7 to M=4. It results in a reduction of a factor ∼10 of the counterstreaming ion-ion mean free path. By adding a low-density ambient gas, it is possible to control the collision of two high-velocity counterstreaming plasma, transitioning from an interpenetrating regime to a regime in agreement with a hydrodynamic description.

AB - We present a study on the impact of a gas atmosphere on the collision of two counterpropagating plasmas (gold and carbon). Imaging optical Thomson scattering data of the plasma collision with and without helium in between have been obtained at the Omega laser facility. Without gas, we observed large scale mixing of colliding gold and carbon ions. Once ambient helium is added, the two plasmas remain separated. The difference in ionic temperature is consistent with a reduction of the maximum Mach number of the flow from M=7 to M=4. It results in a reduction of a factor ∼10 of the counterstreaming ion-ion mean free path. By adding a low-density ambient gas, it is possible to control the collision of two high-velocity counterstreaming plasma, transitioning from an interpenetrating regime to a regime in agreement with a hydrodynamic description.

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ER -

Plasma Collision in a Gas Atmosphere

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