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2023 | OriginalPaper | Chapter

Effect of Viscosity on the Spherical Shock Wave Propagation in a Dusty Gas with Radiation Heat Flux and Exponentially Varying Density

Authors : Ravilisetty Revathi, Dunna Narsimhulu, Addepalli Ramu

Published in: Frontiers in Industrial and Applied Mathematics

Publisher: Springer Nature Singapore

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Abstract

This chapter delves into the complex dynamics of spherical shock wave propagation in a dusty gas, considering the significant influence of viscosity alongside radiation heat flux and exponentially varying density. The authors develop a novel non-similar solution that accounts for viscous dissipation, a crucial factor often neglected in existing literature. By examining the behavior of flow variables such as pressure, density, and velocity behind the shock front, the study provides valuable insights into the thermodynamic equilibrium and dissipative processes at play. The chapter is particularly noteworthy for its comprehensive analysis of the impact of viscosity on shock wave propagation, offering a deeper understanding of this phenomenon in non-ideal gases. The inclusion of radiation heat flux and the consideration of dusty gas conditions further enhance the chapter's relevance, making it a must-read for specialists in the field.
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Metadata
Title
Effect of Viscosity on the Spherical Shock Wave Propagation in a Dusty Gas with Radiation Heat Flux and Exponentially Varying Density
Authors
Ravilisetty Revathi
Dunna Narsimhulu
Addepalli Ramu
Copyright Year
2023
Publisher
Springer Nature Singapore
Book
Frontiers in Industrial and Applied Mathematics

Print ISBN: 978-981-19-7271-3

Electronic ISBN: 978-981-19-7272-0

Copyright Year: 2023

DOI
https://doi.org/10.1007/978-981-19-7272-0_26

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