Statistical analysis of storm-time near-Earth current systems

Currents from the Hot Electron and Ion Drift Integrator (HEIDI) inner magnetospheric model results for all of the 90 intense storms (disturbance storm-time (Dst) minimum < −100 nT) from solar cycle 23 (1996–2005) are calculated, presented, and analyzed. We have categorized these currents into...

Full description

Bibliographic Details
Main Authors: M. W. Liemohn, R. M. Katus, R. Ilie
Format: Article
Language:English
Published: Copernicus Publications 2015-08-01
Series:Annales Geophysicae
Online Access:https://www.ann-geophys.net/33/965/2015/angeo-33-965-2015.pdf
id doaj-18c79bd9dce7490693adfb69da6b8975
record_format Article
spelling doaj-18c79bd9dce7490693adfb69da6b89752020-11-24T22:45:21ZengCopernicus PublicationsAnnales Geophysicae0992-76891432-05762015-08-013396598210.5194/angeo-33-965-2015Statistical analysis of storm-time near-Earth current systemsM. W. Liemohn0R. M. Katus1R. M. Katus2R. Ilie3Atmospheric, Oceanic, and Space Sciences Department, University of Michigan, Ann Arbor, MI USAAtmospheric, Oceanic, and Space Sciences Department, University of Michigan, Ann Arbor, MI USADepartment of Physics and Astronomy, West Virginia University, Morgantown, WV USAAtmospheric, Oceanic, and Space Sciences Department, University of Michigan, Ann Arbor, MI USACurrents from the Hot Electron and Ion Drift Integrator (HEIDI) inner magnetospheric model results for all of the 90 intense storms (disturbance storm-time (Dst) minimum < −100 nT) from solar cycle 23 (1996–2005) are calculated, presented, and analyzed. We have categorized these currents into the various systems that exist in near-Earth space, specifically the eastward and westward symmetric ring current, the partial ring current, the banana current, and the tail current. The current results from each run set are combined by a normalized superposed epoch analysis technique that scales the timeline of each phase of each storm before summing the results. It is found that there is a systematic ordering to the current systems, with the asymmetric current systems peaking during storm main phase (tail current rising first, then the banana current, followed by the partial ring current) and the symmetric current systems peaking during the early recovery phase (westward and eastward symmetric ring current having simultaneous maxima). The median and mean peak amplitudes for the current systems ranged from 1 to 3 MA, depending on the setup configuration used in HEIDI, except for the eastward symmetric ring current, for which the mean never exceeded 0.3 MA for any HEIDI setup. The self-consistent electric field description in HEIDI yielded larger tail and banana currents than the Volland–Stern electric field, while the partial and symmetric ring currents had similar peak values between the two applied electric field models.https://www.ann-geophys.net/33/965/2015/angeo-33-965-2015.pdf
collection DOAJ
language English
format Article
sources DOAJ
author M. W. Liemohn
R. M. Katus
R. M. Katus
R. Ilie
spellingShingle M. W. Liemohn
R. M. Katus
R. M. Katus
R. Ilie
Statistical analysis of storm-time near-Earth current systems
Annales Geophysicae
author_facet M. W. Liemohn
R. M. Katus
R. M. Katus
R. Ilie
author_sort M. W. Liemohn
title Statistical analysis of storm-time near-Earth current systems
title_short Statistical analysis of storm-time near-Earth current systems
title_full Statistical analysis of storm-time near-Earth current systems
title_fullStr Statistical analysis of storm-time near-Earth current systems
title_full_unstemmed Statistical analysis of storm-time near-Earth current systems
title_sort statistical analysis of storm-time near-earth current systems
publisher Copernicus Publications
series Annales Geophysicae
issn 0992-7689
1432-0576
publishDate 2015-08-01
description Currents from the Hot Electron and Ion Drift Integrator (HEIDI) inner magnetospheric model results for all of the 90 intense storms (disturbance storm-time (Dst) minimum < −100 nT) from solar cycle 23 (1996–2005) are calculated, presented, and analyzed. We have categorized these currents into the various systems that exist in near-Earth space, specifically the eastward and westward symmetric ring current, the partial ring current, the banana current, and the tail current. The current results from each run set are combined by a normalized superposed epoch analysis technique that scales the timeline of each phase of each storm before summing the results. It is found that there is a systematic ordering to the current systems, with the asymmetric current systems peaking during storm main phase (tail current rising first, then the banana current, followed by the partial ring current) and the symmetric current systems peaking during the early recovery phase (westward and eastward symmetric ring current having simultaneous maxima). The median and mean peak amplitudes for the current systems ranged from 1 to 3 MA, depending on the setup configuration used in HEIDI, except for the eastward symmetric ring current, for which the mean never exceeded 0.3 MA for any HEIDI setup. The self-consistent electric field description in HEIDI yielded larger tail and banana currents than the Volland–Stern electric field, while the partial and symmetric ring currents had similar peak values between the two applied electric field models.
url https://www.ann-geophys.net/33/965/2015/angeo-33-965-2015.pdf
work_keys_str_mv AT mwliemohn statisticalanalysisofstormtimenearearthcurrentsystems
AT rmkatus statisticalanalysisofstormtimenearearthcurrentsystems
AT rmkatus statisticalanalysisofstormtimenearearthcurrentsystems
AT rilie statisticalanalysisofstormtimenearearthcurrentsystems
_version_ 1725688965134024704