Investigation of the polytropic relationship between density and temperature within interplanetary coronal mass ejections using numerical simulations

Details Investigation of the polytropic relationship between density and temperature within interplanetary coronal mass ejections using numerical simulations Investigation of the polytropic relationship between density and temperature within interplanetary coronal mass ejections using numerical simulations

May 2001

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2001jgr...106.8291r&link_type=abstract

Journal of Geophysical Research, Volume 106, Issue A5, p. 8291-8300

Physics

Plasma Physics

5

Solar Physics, Astrophysics, And Astronomy: Coronal Mass Ejections, Space Plasma Physics: Numerical Simulation Studies, Space Plasma Physics: Shock Waves

Scientific paper

Single-point spacecraft measurements within coronal mass ejections (CMEs) often exhibit a negative correlation between electron density and temperature. At least two opposing interpretations have been suggested for this relationship. If, on one hand, these single spacecraft observations provide direct measures of the polytropic properties of the plasma, then they imply that the polytropic index for the electrons γe is often <1. Moreover, since the electrons carry the bulk of the pressure (via their significantly higher temperature), this further implies that the dynamics of CME evolution are dominated by an effective polytropic index γeff<1. On the other hand, γ<1 implies that as the ejecta propagate away from the Sun and expand, they also heat up; a result clearly at odds with in situ observations. In contrast to these CME intervals, many studies have shown that the quiescent solar wind exhibits a positive correlation between electron density and temperature, suggesting that γe>1. In this study we simulate the evolution of a variety of CME-like disturbances in the solar wind using a one-dimensional, single-fluid model, to address the interpretation of the relationship between electron density and temperature within CMEs at fixed locations in space. Although we strictly impose a polytropic relationship (with γ=constant) throughout our simulations, we demonstrate that a variety of correlations can exist between density and temperature at fixed points. Furthermore, we demonstrate that the presence of only local uncorrelated random fluctuations in density and temperature can produce a negative correlation. Consequently, we conclude that these single-point observations of negative correlations between electron density and temperature cannot be used to infer the value of γe. Instead, we suggest that entropy variations, together with the plasma's tendency to achieve pressure balance with its surroundings, are responsible for the observed profiles.

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