The altitude of green OI 557.7 nm and blue N2+ 427.8 nm aurora

IF 1.7 4区 地球科学 Q3 ASTRONOMY & ASTROPHYSICS
Daniel K. Whiter, Noora Partamies, Björn Gustavsson, Kirsti Kauristie
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引用次数: 1

Abstract

Abstract. We have performed a large statistical study of the peak emission altitude of green O(1D2–1S0) (557.7 nm) and blue N2+ 1 N (427.8 nm) aurora using observations from a network of all-sky cameras stationed across northern Finland and Sweden recorded during seven 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 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 (A3Σu+), with a rate that depends on the product of the N2 and O number densities. Since both number densities decrease with 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 be 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.
极光的高度为绿色OI 557.7 nm和蓝色N2+ 427.8 nm
摘要我们对绿色O(1d2 - 1so0) (557.7 nm)和蓝色N2+ 1n (427.8 nm)极光的峰值发射高度进行了大规模的统计研究,使用的是2000年至2007年7个冬季在芬兰北部和瑞典部署的全天空照相机网络的观测数据。这两种排放通常在114公里左右达到峰值。蓝色峰高分布较绿色峰高偏倚,绿色和蓝色的平均峰高分别为114.84±0.06 km和116.55±0.07 km。我们比较了两种排放的同时测量,结合极光模拟来研究排放的产生机制。在低能电子析出(< ~ 4 keV)过程中,当两种发射峰在约110 km以上时,绿色发射峰比蓝色发射峰低的可能性更大,两者高度差随其平均值而增大。建模表明,在这些条件下,绿线上的状态O(1S)的主要来源是来自激发态N2 (A3Σu+)的能量转移,其速率取决于N2和O数密度的乘积。由于两种数密度都随着海拔的升高而降低,因此N2能量转移产生的O(1S)在海拔较低时达到峰值,而N2电离率仅取决于N2数密度。因此,绿色极光的峰值低于蓝色极光。当两种排放在110公里以下达到峰值时,它们通常在非常相似的高度达到峰值。在低海拔地区,O(1S)的主要来源不应该是N2的能量转移,因为该过程的速率峰值高于N2电离速率和由于长寿命激发的N2在低海拔地区猝灭而产生的蓝色发射。O2+的解离重组似乎最有可能是这些低海拔地区的主要来源,但我们的模型无法完全重现观测结果,这表明可能还有其他未被解释的O(1S)来源。
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来源期刊
Annales Geophysicae
Annales Geophysicae 地学-地球科学综合
CiteScore
4.30
自引率
0.00%
发文量
42
审稿时长
2 months
期刊介绍: Annales Geophysicae (ANGEO) is a not-for-profit international multi- and inter-disciplinary scientific open-access journal in the field of solar–terrestrial and planetary sciences. ANGEO publishes original articles and short communications (letters) on research of the Sun–Earth system, including the science of space weather, solar–terrestrial plasma physics, the Earth''s ionosphere and atmosphere, the magnetosphere, and the study of planets and planetary systems, the interaction between the different spheres of a planet, and the interaction across the planetary system. Topics range from space weathering, planetary magnetic field, and planetary interior and surface dynamics to the formation and evolution of planetary systems.
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