Magnetic local time (MLT) dependence of auroral peak emission height and morphology
Magnetic local time (MLT) dependence of auroral peak emission height and morphology
We investigate the bulk behaviour of auroral structures and peak emission height as a function of magnetic local time (MLT). These data are collected from the Fennoscandian Lapland and Svalbard latitudes from seven identical auroral all-sky cameras (ASC) over about one solar cycle. The analysis focusses on green auroral emission, which is where the morphology is most clearly visible and the number of images is the highest. The typical peak emission height of the green and blue aurora varies from 110km on the nightside to about 118km in the morning MLT over the Lapland region. It stays systematically higher (at 118-120km) at high latitudes (Svalbard) during the nighttime and reaches 140km at around magnetic noon. During high solar wind speed (above 500kms-1), nightside emission heights appear about 5km lower than during slow solar wind speed (below 400kms-1). The sign of the interplanetary magnetic field (IMF) has nearly no effect on the emission heights in the night sector, but the northward IMF causes lower emission heights at dawn over Lapland and during the noon hours over Svalbard. While the former is interpreted as a change in the particle population within the field-of-view (FoV), the latter is rather due to the movement of the cusp location due to the IMF orientation. The morning sector heights also show a pronounced difference when previously detected pulsating aurora (PsA) events have been excluded/included in the dataset, suggesting that this type of aurora is a dominant phenomenon in the morning and an important dissipation mechanism. An increase of complex auroral structures in the midnight hours agrees with the average substorm occurrence. This increase is amplified during stronger solar wind driving and during higher geomagnetic activity (as measured by auroral electrojet index, AL). During high solar wind speed, the high latitude auroral evolution shows particularly complex morphology, which is not limited to the nightside but rather only excludes the magnetic noon hours. An increase in the geomagnetic activity further enhances the structural complexity of the aurora in the morning sector.
605-618
Partamies, Noora
7219021b-a268-41eb-8e75-80550b7cf78f
Whiter, Daniel
9a30d7b6-ea41-44fb-bd52-3ff1964eca5c
Kauristie, Kirsti
6c818f17-8fe5-4911-9c62-055ae136d88d
Massetti, Stefano
32e665b3-2bc2-43c4-a23d-498ada2d0240
12 October 2022
Partamies, Noora
7219021b-a268-41eb-8e75-80550b7cf78f
Whiter, Daniel
9a30d7b6-ea41-44fb-bd52-3ff1964eca5c
Kauristie, Kirsti
6c818f17-8fe5-4911-9c62-055ae136d88d
Massetti, Stefano
32e665b3-2bc2-43c4-a23d-498ada2d0240
Partamies, Noora, Whiter, Daniel, Kauristie, Kirsti and Massetti, Stefano
(2022)
Magnetic local time (MLT) dependence of auroral peak emission height and morphology.
Annales Geophysicae, 40 (5), .
(doi:10.5194/angeo-40-605-2022).
Abstract
We investigate the bulk behaviour of auroral structures and peak emission height as a function of magnetic local time (MLT). These data are collected from the Fennoscandian Lapland and Svalbard latitudes from seven identical auroral all-sky cameras (ASC) over about one solar cycle. The analysis focusses on green auroral emission, which is where the morphology is most clearly visible and the number of images is the highest. The typical peak emission height of the green and blue aurora varies from 110km on the nightside to about 118km in the morning MLT over the Lapland region. It stays systematically higher (at 118-120km) at high latitudes (Svalbard) during the nighttime and reaches 140km at around magnetic noon. During high solar wind speed (above 500kms-1), nightside emission heights appear about 5km lower than during slow solar wind speed (below 400kms-1). The sign of the interplanetary magnetic field (IMF) has nearly no effect on the emission heights in the night sector, but the northward IMF causes lower emission heights at dawn over Lapland and during the noon hours over Svalbard. While the former is interpreted as a change in the particle population within the field-of-view (FoV), the latter is rather due to the movement of the cusp location due to the IMF orientation. The morning sector heights also show a pronounced difference when previously detected pulsating aurora (PsA) events have been excluded/included in the dataset, suggesting that this type of aurora is a dominant phenomenon in the morning and an important dissipation mechanism. An increase of complex auroral structures in the midnight hours agrees with the average substorm occurrence. This increase is amplified during stronger solar wind driving and during higher geomagnetic activity (as measured by auroral electrojet index, AL). During high solar wind speed, the high latitude auroral evolution shows particularly complex morphology, which is not limited to the nightside but rather only excludes the magnetic noon hours. An increase in the geomagnetic activity further enhances the structural complexity of the aurora in the morning sector.
Text
Partamies et al. 2022, Ann. Geophys, Accepted version
- Accepted Manuscript
Text
angeo-40-605-2022
- Version of Record
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Accepted/In Press date: 19 September 2022
Published date: 12 October 2022
Identifiers
Local EPrints ID: 472005
URI: http://eprints.soton.ac.uk/id/eprint/472005
ISSN: 0992-7689
PURE UUID: 03f4bbbd-e73e-4f30-a7db-cd5d45ea59d3
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Date deposited: 23 Nov 2022 17:54
Last modified: 17 Mar 2024 03:14
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Author:
Noora Partamies
Author:
Kirsti Kauristie
Author:
Stefano Massetti
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