The open flux problem

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Linker, J. A., Caplan, R. M., Downs, C., Riley, P., Mikic, Z., Lionello, R., Henney, C. J., Arge, C. N., Liu, Y., Derosa, M. L., Yeates, A. and Owens, M. J. ORCID: https://orcid.org/0000-0003-2061-2453 (2017) The open flux problem. The Astrophysical Journal, 848 (1). 70. ISSN 0004-637X doi: 10.3847/1538-4357/aa8a70

Abstract/Summary

The heliospheric magnetic field is of pivotal importance in solar and space physics. The field is rooted in the Sun's photosphere, where it has been observed for many years. Global maps of the solar magnetic field based on full-disk magnetograms are commonly used as boundary conditions for coronal and solar wind models. Two primary observational constraints on the models are (1) the open field regions in the model should approximately correspond to coronal holes (CHs) observed in emission and (2) the magnitude of the open magnetic flux in the model should match that inferred from in situ spacecraft measurements. In this study, we calculate both magnetohydrodynamic and potential field source surface solutions using 14 different magnetic maps produced from five different types of observatory magnetograms, for the time period surrounding 2010 July. We have found that for all of the model/map combinations, models that have CH areas close to observations underestimate the interplanetary magnetic flux, or, conversely, for models to match the interplanetary flux, the modeled open field regions are larger than CHs observed in EUV emission. In an alternative approach, we estimate the open magnetic flux entirely from solar observations by combining automatically detected CHs for Carrington rotation 2098 with observatory synoptic magnetic maps. This approach also underestimates the interplanetary magnetic flux. Our results imply that either typical observatory maps underestimate the Sun's magnetic flux, or a significant portion of the open magnetic flux is not rooted in regions that are obviously dark in EUV and X-ray emission.

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Item Type	Article
URI	https://reading-clone.eprints-hosting.org/id/eprint/73134
Item Type	Article
Refereed	Yes
Divisions	Science > School of Mathematical, Physical and Computational Sciences > Department of Meteorology
Publisher	American Astronomical Society
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Funders:	Science and Technology Facilities Council	The sponsoring bodies who contributed funding for the creation of this item. Example: NERC Example: The Royal Society of Chemistry A pick list of funders may appear as you type in the funder's name in full or as an acronym. Select a correct match to complete the field or type in a new entry in full. For new entries, the full name is preferred.
Projects:	Reading solar system science Funded by: Science and Technology Facilities Council (ST/M000885/1 - £599,663) Local Lead (PI): Clare Watt Project Lead: Clare Emily Jane Watt 1 April 2015 - 31 March 2018	Click Add to select your project (received at Reading) from an autocomplete list.

Deposit Details

Date Deposited:	30 Oct 2017 16:29	Date item deposited into CentAUR
Last Modified:	09 Jun 2024 03:11	Date item last modified

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