The altitude of green OI 557.7 nm and blue N2+ 427.8 nm aurora
The altitude of green OI 557.7 nm and blue N2+ 427.8 nm aurora
We have performed a large statistical study of the peak emission altitude of green O(1D2–1S0) (557.7 nm) and blue N2+ 1N (427.8 nm) aurora using observations from a network of all-sky cameras stationed across northern Finland and Sweden recorded during 7 winter seasons from 2000 to 2007. Both emissions were found to typically peak at about 114 km. The distribution of blue peak altitudes is more skewed than that for the green, and the mean peak emission altitudes were 114.84 ± 0.06 km and 116.55 ± 0.07 km for green and blue emissions, respectively. We compare simultaneous measurements of the two emissions in combination with auroral modelling to investigate the emission production mechanisms.
During low energy electron precipitation (<∼4 keV), when the two emissions peak above about 110 km, it is more likely for the green emission to peak below the blue emission than vice versa, with the difference between the two heights increasing with their average. Modelling has shown that under these conditions the dominant source of O(1S), the upper state of the green line, is energy transfer from excited N2(A3∑+u), with a rate that depends on the product of the N2 and O number densities. Since both number densities decrease to higher altitude, the production of O(1S) by energy transfer from N2 peaks at lower altitude than the N2 ionisation rate, which depends on the N2 number density only. Consequently, the green aurora peaks below the blue aurora.
When the two emissions peak below about 110 km they typically peak at very similar altitude. The dominant source of O(1S) at low altitudes must not be energy transfer from N2, since the rate of that process peaks above the N2 ionisation rate and blue emission due to quenching of the long-lived excited N2 at low altitudes. Dissociative recombination of O2+ seems most likely to a major source at these low altitudes, but our model is unable to reproduce observations fully, suggesting there may be additional sources of O(1S) unaccounted for.
Whiter, Daniel
9a30d7b6-ea41-44fb-bd52-3ff1964eca5c
Partamies, Noora
7219021b-a268-41eb-8e75-80550b7cf78f
Gustavsson, Björn
d88050c7-3139-4b1f-a0c1-a70d7288a3b6
Kauristie, Kirsti
6c818f17-8fe5-4911-9c62-055ae136d88d
6 January 2023
Whiter, Daniel
9a30d7b6-ea41-44fb-bd52-3ff1964eca5c
Partamies, Noora
7219021b-a268-41eb-8e75-80550b7cf78f
Gustavsson, Björn
d88050c7-3139-4b1f-a0c1-a70d7288a3b6
Kauristie, Kirsti
6c818f17-8fe5-4911-9c62-055ae136d88d
Whiter, Daniel, Partamies, Noora, Gustavsson, Björn and Kauristie, Kirsti
(2023)
The altitude of green OI 557.7 nm and blue N2+ 427.8 nm aurora.
Annales Geophysicae.
(doi:10.5194/angeo-2022-23).
Abstract
We have performed a large statistical study of the peak emission altitude of green O(1D2–1S0) (557.7 nm) and blue N2+ 1N (427.8 nm) aurora using observations from a network of all-sky cameras stationed across northern Finland and Sweden recorded during 7 winter seasons from 2000 to 2007. Both emissions were found to typically peak at about 114 km. The distribution of blue peak altitudes is more skewed than that for the green, and the mean peak emission altitudes were 114.84 ± 0.06 km and 116.55 ± 0.07 km for green and blue emissions, respectively. We compare simultaneous measurements of the two emissions in combination with auroral modelling to investigate the emission production mechanisms.
During low energy electron precipitation (<∼4 keV), when the two emissions peak above about 110 km, it is more likely for the green emission to peak below the blue emission than vice versa, with the difference between the two heights increasing with their average. Modelling has shown that under these conditions the dominant source of O(1S), the upper state of the green line, is energy transfer from excited N2(A3∑+u), with a rate that depends on the product of the N2 and O number densities. Since both number densities decrease to higher altitude, the production of O(1S) by energy transfer from N2 peaks at lower altitude than the N2 ionisation rate, which depends on the N2 number density only. Consequently, the green aurora peaks below the blue aurora.
When the two emissions peak below about 110 km they typically peak at very similar altitude. The dominant source of O(1S) at low altitudes must not be energy transfer from N2, since the rate of that process peaks above the N2 ionisation rate and blue emission due to quenching of the long-lived excited N2 at low altitudes. Dissociative recombination of O2+ seems most likely to a major source at these low altitudes, but our model is unable to reproduce observations fully, suggesting there may be additional sources of O(1S) unaccounted for.
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Accepted/In Press date: 17 November 2022
Published date: 6 January 2023
Identifiers
Local EPrints ID: 472847
URI: http://eprints.soton.ac.uk/id/eprint/472847
ISSN: 0992-7689
PURE UUID: 7e516943-ce0b-43ad-9aed-6131ef3159da
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Date deposited: 20 Dec 2022 17:35
Last modified: 17 Mar 2024 03:14
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Contributors
Author:
Noora Partamies
Author:
Björn Gustavsson
Author:
Kirsti Kauristie
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