The Astrophysical Journal (Jan 2024)

Turbulent Heating of Solar Wind Plasma Downstream of Magnetohydrodynamic Shocks

  • Alexander Pitňa,
  • Jana Šafránková,
  • Zdeněk Němeček,
  • Gilbert Pi,
  • Gary Zank,
  • Lingling Zhao,
  • Laxman Adhikari,
  • Masaru Nakanotani

DOI
https://doi.org/10.3847/1538-4357/ad1c64
Journal volume & issue
Vol. 963, no. 2
p. 161

Abstract

Read online

Interplanetary (IP) shocks are believed to play a significant role in both amplifying the background level of turbulent fluctuations and in heating the bulk solar wind (SW). This study investigates the thermodynamic properties downstream of IP shocks. We examine the temperature, density, and specific entropy changes in the shocked plasma, taking into consideration the geometric aspects of IP shock propagation within the expanding SW. Specifically, in our analysis, we account for the fact that any particular temporal range of one-point measurement may correspond to vastly different physically relevant temporal and/or spatial dimensions, such as the age of the shocked plasma and/or radial distance to the place where the plasma encountered the shock. Thus, our approach resolves the contradictions in previously reported temperature and specific entropy profiles in downstream regions and suggests that downstream regions exhibit greater turbulent heating compared to the pristine SW. This may contribute to the overall heating of the SW plasma. The paper presents a phenomenological parameter to predict specific entropy profiles and demonstrates the consistency of the proposed model with observations. We discuss the implications of these results for the thermodynamics of the SW beyond 1 au.

Keywords