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Fluid Dynamics

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01-12-2022

A Two-Dimensional Radiative Gasdynamic Model of the Aerophysics of Descent Space Capsules

Author: S. T. Surzhikov

Published in: Fluid Dynamics | Special Issue 2/2022

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Abstract

A computational-theoretical method for the study of radiative gas dynamics and aerophysics of descent space capsules (SCs) designed to enter the dense layers of planetary atmospheres and return to Earth is presented.

next article Computational Interpretation of Classical Rose–Stark Experimental Data

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Title: A Two-Dimensional Radiative Gasdynamic Model of the Aerophysics of Descent Space Capsules
Author: S. T. Surzhikov
Publication date: 01-12-2022
Publisher: Pleiades Publishing
Published in: Fluid Dynamics / Issue Special Issue 2/2022
Print ISSN: 0015-4628
Electronic ISSN: 1573-8507
DOI: https://doi.org/10.1134/S0015462822100597

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Other articles of this Special Issue 2/2022

The Role of the Spectral Lines of Atoms and Ions in Radiative Heating of the Surfaces of Space Capsules

The Radiative Gas Dynamics of Spherical Spacecraft in the Martian Atmosphere

The Radiative Gas Dynamics of the Apollo-4 Command Module during Superorbital Earth Entry

Radiative Gas Dynamics of the Orion Descent Space Capsule in the Earth’s Atmosphere

An Analysis of Experimental Data on Air Ionization in a Compressed Layer near the Surface of a Spherically Blunted Cone at a Velocity about 5 km/s

Numerical Models of Electron Kinetics in the Problem of Transverse Flow around a Cylindrical Model by a Supersonic Gas Flow

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