Ion charge states and potential geoeffectiveness: the role of coronal spectroscopy for space-weather forecasting

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Owens, M. J. ORCID: https://orcid.org/0000-0003-2061-2453, Lockwood, M. ORCID: https://orcid.org/0000-0002-7397-2172 and Barnard, L. A. ORCID: https://orcid.org/0000-0001-9876-4612 (2018) Ion charge states and potential geoeffectiveness: the role of coronal spectroscopy for space-weather forecasting. Space Weather, 16 (6). pp. 694-703. ISSN 1542-7390 doi: 10.1029/2018SW001855

Abstract/Summary

Severe space-weather is driven by interplanetary coronal mass ejections (ICMEs), episodic eruptions of solar plasma and magnetic flux that travel out through the heliosphere and can perturb the Earth’s magnetosphere, ionosphere and upper atmosphere. In order for space-weather forecasts to allow effective mitigating action, forecasts must be made as early as possible, necessitating identification of potentially “geoeffective” ICMEs close to the Sun. This presents two challenges. Firstly, geoeffectiveness is primarily determined by the magnetic field intensity and orientation, both of which are difficult to measure close to the Sun. Secondly, the magnetic field evolves in transit between the Sun and the Earth, sometimes in a highly non-linear way. Conversely, solar wind ion charge states, such as the ratio of O7+ to O6+, can be observed near the Sun through coronal spectroscopy and are fixed by the electron temperature at the coronal height where ion-electron collisions are last possible as the ICME erupts. After this point, they are said to be “frozen in” as they do not evolve further as the ICME propagates through the solar wind. In this study we show that ions charge states, while not geoeffective in and of themselves, act as strong markers for the geoeffectiveness of the ICME. The probability of severe space weather is around seven times higher in “hot” ICMEs than “cold” ICMEs, as defined by O7+/O6+. We suggest that coronal spectroscopy of ICMEs could complement current forecasting techniques, providing valuable additional information about potential geoeffectiveness.

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Item Type	Article
URI	https://reading-clone.eprints-hosting.org/id/eprint/77449
Item Type	Article
Refereed	Yes
Divisions	Science > School of Mathematical, Physical and Computational Sciences > Department of Meteorology
Publisher	American Geophysical Union
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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.

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Date Deposited:	07 Jun 2018 11:15	Date item deposited into CentAUR
Last Modified:	16 Jan 2025 02:36	Date item last modified

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