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Main Authors: Garcia-Rubio, F., Tranchant, V., Hansen, E. C., Tabassum, R., Reyes, A., Rahman, H. U., Ney, P., Ruskov, E., Tzeferacos, P.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.19445
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author Garcia-Rubio, F.
Tranchant, V.
Hansen, E. C.
Tabassum, R.
Reyes, A.
Rahman, H. U.
Ney, P.
Ruskov, E.
Tzeferacos, P.
author_facet Garcia-Rubio, F.
Tranchant, V.
Hansen, E. C.
Tabassum, R.
Reyes, A.
Rahman, H. U.
Ney, P.
Ruskov, E.
Tzeferacos, P.
contents The temporal evolution of weak shocks in radiative media is theoretically investigated in this work. The structure of radiative shocks has traditionally been studied in a stationary framework. Their systematic classification is complex because layers of optically thin and thick regions alternate to form a radiatively-driven precursor and a temperature-relaxation layer, between which the hydrodynamic shock is embedded. In this work, we analyze the formation of weak shocks when two radiative plasmas with different pressures are put in contact. Applying a reductive perturbative method yields a Burgers-type equation that governs the temporal evolution of the perturbed variables including the radiation field. The conditions upon which optically thin and thick solutions exist have been derived and expressed as a function of the shock strength and Boltzmann number. Below a certain Boltzmann number threshold, weak shocks always become optically thick asymptotically in time, while thin solutions appear as transitory structures. The existence of an optically thin regime is related to the presence of an overdense layer in the compressed material. Scaling laws for the characteristic formation time and shock width are provided for each regime. The theoretical analysis is supported by FLASH simulations, and a comprehensive test-case has been designed to benchmark radiative hydrodynamic codes.
format Preprint
id arxiv_https___arxiv_org_abs_2405_19445
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Shock Wave Formation in Radiative Plasmas
Garcia-Rubio, F.
Tranchant, V.
Hansen, E. C.
Tabassum, R.
Reyes, A.
Rahman, H. U.
Ney, P.
Ruskov, E.
Tzeferacos, P.
Plasma Physics
High Energy Physics - Theory
Fluid Dynamics
The temporal evolution of weak shocks in radiative media is theoretically investigated in this work. The structure of radiative shocks has traditionally been studied in a stationary framework. Their systematic classification is complex because layers of optically thin and thick regions alternate to form a radiatively-driven precursor and a temperature-relaxation layer, between which the hydrodynamic shock is embedded. In this work, we analyze the formation of weak shocks when two radiative plasmas with different pressures are put in contact. Applying a reductive perturbative method yields a Burgers-type equation that governs the temporal evolution of the perturbed variables including the radiation field. The conditions upon which optically thin and thick solutions exist have been derived and expressed as a function of the shock strength and Boltzmann number. Below a certain Boltzmann number threshold, weak shocks always become optically thick asymptotically in time, while thin solutions appear as transitory structures. The existence of an optically thin regime is related to the presence of an overdense layer in the compressed material. Scaling laws for the characteristic formation time and shock width are provided for each regime. The theoretical analysis is supported by FLASH simulations, and a comprehensive test-case has been designed to benchmark radiative hydrodynamic codes.
title Shock Wave Formation in Radiative Plasmas
topic Plasma Physics
High Energy Physics - Theory
Fluid Dynamics
url https://arxiv.org/abs/2405.19445