Link between laboratory and astrophysical radiative shocks

C. Michaut; E. Falize; C. Cavet; S. Bouquet; M. Koenig; T. Vinci; B. Loupias

doi:10.1088/1742-6596/112/4/042013

Link between laboratory and astrophysical radiative shocks

C. Michaut, E. Falize, C. Cavet, S. Bouquet, M. Koenig, T. Vinci, B. Loupias

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

Abstract

This work provides analytical solutions describing the post-shock structure of radiative shocks growing in astrophysics and in laboratory. The equations including a cooling function Λ α ^ϵ Ρ^ζ x^θ are solved for any values of the exponents ϵ, ζ and θ. This modeling is appropriate to astrophysics as the observed radiative shocks arise in optically thin media. In contrast, in laboratory, radiative shocks performed using high-power lasers present a radiative precursor because the plasma is more or less optically thick. We study the post-shock region in the laboratory case and compare with astrophysical shock structure. In addition, we attempt to use the same equations to describe the radiative precursor, but the cooling function is slightly modified. In future experiments we will probe the PSR using X-ray diagnostics. These new experimental results will allow to validate our astrophysical numerical codes.

Original language	English
Article number	042013
Journal	Journal of Physics: Conference Series
Volume	112
Issue number	Part 4
DOIs	https://doi.org/10.1088/1742-6596/112/4/042013
Publication status	Published - 12 Jun 2008
Externally published	Yes
Event	5th International Conference on Inertial Fusion Sciences and Applications, IFSA 2007 - Kobe, Japan Duration: 9 Sept 2007 → 14 Sept 2007

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10.1088/1742-6596/112/4/042013

Cite this

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title = "Link between laboratory and astrophysical radiative shocks",

abstract = "This work provides analytical solutions describing the post-shock structure of radiative shocks growing in astrophysics and in laboratory. The equations including a cooling function Λ α ϵ Ρζ xθ are solved for any values of the exponents ϵ, ζ and θ. This modeling is appropriate to astrophysics as the observed radiative shocks arise in optically thin media. In contrast, in laboratory, radiative shocks performed using high-power lasers present a radiative precursor because the plasma is more or less optically thick. We study the post-shock region in the laboratory case and compare with astrophysical shock structure. In addition, we attempt to use the same equations to describe the radiative precursor, but the cooling function is slightly modified. In future experiments we will probe the PSR using X-ray diagnostics. These new experimental results will allow to validate our astrophysical numerical codes.",

author = "C. Michaut and E. Falize and C. Cavet and S. Bouquet and M. Koenig and T. Vinci and B. Loupias",

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doi = "10.1088/1742-6596/112/4/042013",

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TY - JOUR

T1 - Link between laboratory and astrophysical radiative shocks

AU - Michaut, C.

AU - Falize, E.

AU - Cavet, C.

AU - Bouquet, S.

AU - Koenig, M.

AU - Vinci, T.

AU - Loupias, B.

PY - 2008/6/12

Y1 - 2008/6/12

N2 - This work provides analytical solutions describing the post-shock structure of radiative shocks growing in astrophysics and in laboratory. The equations including a cooling function Λ α ϵ Ρζ xθ are solved for any values of the exponents ϵ, ζ and θ. This modeling is appropriate to astrophysics as the observed radiative shocks arise in optically thin media. In contrast, in laboratory, radiative shocks performed using high-power lasers present a radiative precursor because the plasma is more or less optically thick. We study the post-shock region in the laboratory case and compare with astrophysical shock structure. In addition, we attempt to use the same equations to describe the radiative precursor, but the cooling function is slightly modified. In future experiments we will probe the PSR using X-ray diagnostics. These new experimental results will allow to validate our astrophysical numerical codes.

AB - This work provides analytical solutions describing the post-shock structure of radiative shocks growing in astrophysics and in laboratory. The equations including a cooling function Λ α ϵ Ρζ xθ are solved for any values of the exponents ϵ, ζ and θ. This modeling is appropriate to astrophysics as the observed radiative shocks arise in optically thin media. In contrast, in laboratory, radiative shocks performed using high-power lasers present a radiative precursor because the plasma is more or less optically thick. We study the post-shock region in the laboratory case and compare with astrophysical shock structure. In addition, we attempt to use the same equations to describe the radiative precursor, but the cooling function is slightly modified. In future experiments we will probe the PSR using X-ray diagnostics. These new experimental results will allow to validate our astrophysical numerical codes.

U2 - 10.1088/1742-6596/112/4/042013

DO - 10.1088/1742-6596/112/4/042013

M3 - Conference article

AN - SCOPUS:84996490755

SN - 1742-6588

VL - 112

JO - Journal of Physics: Conference Series

JF - Journal of Physics: Conference Series

IS - Part 4

M1 - 042013

T2 - 5th International Conference on Inertial Fusion Sciences and Applications, IFSA 2007

Y2 - 9 September 2007 through 14 September 2007

ER -

Link between laboratory and astrophysical radiative shocks

Abstract

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