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A porcupine Sun? Implications for the solar wind and Earth

Published online by Cambridge University Press:  05 July 2012

Sarah E. Gibson
Affiliation:
NCAR/HAO, 3080 Center Green Dr., Boulder, CO email: sgibson@ucar.edu
Liang Zhao
Affiliation:
NCAR/HAO, 3080 Center Green Dr., Boulder, CO email: sgibson@ucar.edu
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Abstract

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The recent minimum was unusually long, and it was not just the case of the “usual story” slowed down. The coronal magnetic field never became completely dipolar as in recent Space Age minima, but rather gradually evolved into an (essentially axisymmetric) global configuration possessing mixed open and closed magnetic structures at many latitudes. In the process, the impact of the solar wind at the Earth went from resembling that from a sequence of rotating “fire-hoses” to what might be expected from a weak, omnidirectional “lawn-sprinkler”. The previous (1996) solar minimum was a more classic dipolar configuration, and was characterized by slow wind of hot origin localized to the heliospheric current sheet, and fast wind of cold origin emitted from polar holes, but filling most of the heliosphere. In contrast, the more recent minimum solar wind possessed a broad range of speeds and source temperatures (although cooler overall than the prior minimum). We discuss possible connections between these observations and the near-radial expansion and small spatial scales characteristic of the recent minimum's porcupine-like magnetic field.

Type
Contributed Papers
Copyright
Copyright © International Astronomical Union 2012

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