The Turbulent Cascade and Proton Heating in the Solar Wind During Solar Minimum

Jesse T. Coburn; Charles W. Smith; Bernard J. Vasquez; Julia Stawarz

doi:10.1063/1.4811009

The Turbulent Cascade and Proton Heating in the Solar Wind During Solar Minimum

Jesse T. Coburn, Charles W. Smith, Bernard J. Vasquez, Julia Stawarz

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Solar wind measurements at 1 AU during the recent solar minimum and previous studies of solar maximum provide an opportunity to study the effects of the changing solar cycle on in situ heating. Our interest is to compare the levels of activity associated with turbulence and proton heating. Large-scale shears in the flow caused by transient activity are a source that drives turbulence that heats the solar wind, but as the solar cycle progresses the dynamics that drive the turbulence and heat the medium are likely to change. The application of third-moment theory to Advanced Composition Explorer (ACE) data gives the turbulent energy cascade rate which is not seen to vary with the solar cycle. Likewise, an empirical heating rate shows no significan changes in proton heating over the cycle.

Original language	English
Journal	AIP Conference Proceedings
Volume	1539
Issue number	1
DOIs	https://doi.org/10.1063/1.4811009
Publication status	Published - 2013
Externally published	Yes

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10.1063/1.4811009

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abstract = "Solar wind measurements at 1 AU during the recent solar minimum and previous studies of solar maximum provide an opportunity to study the effects of the changing solar cycle on in situ heating. Our interest is to compare the levels of activity associated with turbulence and proton heating. Large-scale shears in the flow caused by transient activity are a source that drives turbulence that heats the solar wind, but as the solar cycle progresses the dynamics that drive the turbulence and heat the medium are likely to change. The application of third-moment theory to Advanced Composition Explorer (ACE) data gives the turbulent energy cascade rate which is not seen to vary with the solar cycle. Likewise, an empirical heating rate shows no significan changes in proton heating over the cycle.",

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AB - Solar wind measurements at 1 AU during the recent solar minimum and previous studies of solar maximum provide an opportunity to study the effects of the changing solar cycle on in situ heating. Our interest is to compare the levels of activity associated with turbulence and proton heating. Large-scale shears in the flow caused by transient activity are a source that drives turbulence that heats the solar wind, but as the solar cycle progresses the dynamics that drive the turbulence and heat the medium are likely to change. The application of third-moment theory to Advanced Composition Explorer (ACE) data gives the turbulent energy cascade rate which is not seen to vary with the solar cycle. Likewise, an empirical heating rate shows no significan changes in proton heating over the cycle.

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The Turbulent Cascade and Proton Heating in the Solar Wind During Solar Minimum

Abstract

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