Electron impact dissociative excitation of O<sub>2</sub>: 2. Absolute emission cross sections of the OI(130.4 nm) and OI(135.6 nm) lines

Kanik, I.; Norén, C.; Makarov, O. P.; Vattipalle, Prahlad; Ajello, J. M.; Shemansky, D. E.

doi:10.1029/2000je001423

Cited by 70 publications

(84 citation statements)

References 41 publications

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“…O + -O − neutralization may also play a role (around 5 % of the total emission), especially in the mid-latitude ionosphere (Meier, 1991;Dymond et al, 2000) and at low altitudes. These two last mechanisms as well as cascades from 5 P upper states (Kanik et al, 2003) will not be considered here as a lower estimate is sought. Processes (a) and (b) contribute to more than 85 % of the total brightness (Strickland and Anderson, 1983;Strickland et al, 1993) and processes (c) and (d) to around 10 % or less (Dymond et al, 2000, and this study).…”

Section: Ionospheric Response: Modelling the Optical Emissionsmentioning

confidence: 99%

“…The most recent cross-sections for processes (a) and (b) used in the computation are Laher and Gilmore (1990) and Kanik et al (2003), respectively. The recommendation of Laher and Gilmore (1990) for process (a), deduced from calculations, is in qualitative agreement with the laboratory measurements reported by Stone and Zipf (1974), later corrected by Zipf and Erdman (1985) and Doering and Gulcicek (1989); the uncertainty reaches 50 %.…”

Section: Ionospheric Response: Modelling the Optical Emissionsmentioning

confidence: 99%

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Polar cap arcs from the magnetosphere to the ionosphere: kinetic modelling and observations by Cluster and TIMED

et al. 2012

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Abstract. On 1 April 2004 the GUVI imager onboard the TIMED spacecraft spots an isolated and elongated polar cap arc. About 20 min later, the Cluster satellites detect an isolated upflowing ion beam above the polar cap. Cluster observations show that the ions are accelerated upward by a quasistationary electric field. The field-aligned potential drop is estimated to about 700 V and the upflowing ions are accompanied by a tenuous population of isotropic protons with a temperature of about 500 eV.The magnetic footpoints of the ion outflows observed by Cluster are situated in the prolongation of the polar cap arc observed by TIMED GUVI. The upflowing ion beam and the polar cap arc may be different signatures of the same phenomenon, as suggested by a recent statistical study of polar cap ion beams using Cluster data.We use Cluster observations at high altitude as input to a quasi-stationary magnetosphere-ionosphere (MI) coupling model. Using a Knight-type current-voltage relationship and the current continuity at the topside ionosphere, the model computes the energy spectrum of precipitating electrons at the top of the ionosphere corresponding to the generator electric field observed by Cluster. The MI coupling model provides a field-aligned potential drop in agreement with Cluster observations of upflowing ions and a spatial scale of the polar cap arc consistent with the optical observations by TIMED. The computed energy spectrum of the precipitating electrons is used as input to the Trans4 ionospheric transport code. This 1-D model, based on Boltzmann's kinetic formalism, takes into account ionospheric processes such as photoionization and electron/proton precipitation, and computes the optical and UV emissions due to precipitating electrons. The emission rates provided by the Trans4 code are compared to the optical observations by TIMED. They are similar in size and intensity. Data and modelling results are consistent with the scenario of quasi-static acceleration of electrons that generate a polar cap arc as they precipitate in the ionosphere. The detailed observations of the acceleration region by Cluster and the large scale image of the polar cap arc provided by TIMED are two different features of the same phenomenon. Combined together, they bring new light on the configuration of the high-latitude magnetosphere during prolonged periods of Northward IMF. Possible implications of the modelling results for optical observations of polar cap arcs are also discussed.

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Section: Ionospheric Response: Modelling the Optical Emissionsmentioning

confidence: 99%

Section: Ionospheric Response: Modelling the Optical Emissionsmentioning

confidence: 99%

Polar cap arcs from the magnetosphere to the ionosphere: kinetic modelling and observations by Cluster and TIMED

et al. 2012

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“…Model aurora images are generated by calculating the expected morphology from an electron-excited atmosphere consisting of O 2 , O, and H 2 O based on the available cross sections for electron impact (dissociative) excitation of the neutrals (38)(39)(40)(41). To be consistent with previous estimations we further apply the constant electron parameters used in previous aurora studies (5)(6)(7)14): a total electron density of 40 cm −3 , a thermal electron population with a temperature of T e = 20 eV, and a suprathermal population with T e = 250 eV and a 2% mixing ratio.…”

Section: Aurora Modelmentioning

confidence: 99%

Orbital apocenter is not a sufficient condition for HST/STIS detection of Europa’s water vapor aurora

Roth

Retherford

Saur

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

113

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Significance Images of Europa’s UV aurora taken by the Hubble Space Telescope in December 2012 have revealed local hydrogen and oxygen emissions in intensity ratios that identify the source as electron impact excitation of water molecules. The existence of water vapor plumes as a source for the detected localized water vapor and the possible accessibility of subsurface liquid water reservoirs at these locations have important implications for the exploration of Europa’s potentially habitable environments. The observations reported here tested whether orbital position near the apocenter is an essential requirement for plume activity. Only an upper limit on the amount of water vapor was obtained. Orbital position is therefore not a sufficient condition for detecting plumes and they may be episodic events.

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“…Absolute electron impact emission cross-section studies for metastable species rely on a LBH emission glow model to extrapolate signal outside the FOV. Two metastable species have been studied by this method in our laboratory: the LBH band system (AS85) from direct excitation of N 2 and the 135.6 nm atomic O 5 S emission [Kanik et al, 2003] from dissociative excitation of O 2 . The lifetime of the a 1 P g state has been, until now, uncertain, with experiments and theory reporting values that typically range from 54 ms to 170 ms.…”

Section: The Lbh Glow Correctionmentioning

confidence: 99%

Laboratory studies of UV emissions from proton impact on N₂: The Lyman-Birge-Hopfield band system for aurora analysis

et al. 2011

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[1] We have measured the emission cross sections of the Lyman-Birge-Hopfield (LBH) a 1 P g − X 1 S g + band system and several atomic nitrogen (N I) multiplets (1200, 1243, 1493 Å) by H + (proton) impact on N 2 over an impact energy range of 1-7 keV. The peak proton-impact-induced emission cross section of the LBH band system (1260-2500 Å) was measured to be 5.05 ± 1.52 × 10 −17 cm 2 at 7 keV. To the best of our knowledge, the present LBH emission cross sections are reported for the first time in the far ultraviolet (FUV) wavelength range of 1100-1600 Å. The proton energy range in this study, when coupled with previously published 10-100 keV proton excited emissions of N I multiplets, provides a wide energy range of emission cross sections for proton energy loss transport codes. This energy range includes the peak cross section and the energy range for Born scaling. The reported measurements lead to an important component of monoenergetic yields for proton FUV auroral emission. Such yields, based on emission cross sections and transport modeling, allowed for convenient comparison of emission efficiencies between proton and electron aurora. In addition, we have measured the H Ly a, LBH, and N I multiplet emission cross sections for H 2 + and H 3 + ion impact on N 2 at 5 keV and found that the magnitude of H Ly a emission cross section, s em (Ly a), follows in the order of impact ion mass H 3 + > H 2 + > H + .Citation: Ajello, J. M., R. S. Mangina, D. J. Strickland, and D. Dziczek (2011), Laboratory studies of UV emissions from proton impact on N 2 : The Lyman-Birge-Hopfield band system for aurora analysis,

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Electron impact dissociative excitation of O₂: 2. Absolute emission cross sections of the OI(130.4 nm) and OI(135.6 nm) lines

Cited by 70 publications

References 41 publications

Polar cap arcs from the magnetosphere to the ionosphere: kinetic modelling and observations by Cluster and TIMED

Polar cap arcs from the magnetosphere to the ionosphere: kinetic modelling and observations by Cluster and TIMED

Orbital apocenter is not a sufficient condition for HST/STIS detection of Europa’s water vapor aurora

Laboratory studies of UV emissions from proton impact on N₂: The Lyman-Birge-Hopfield band system for aurora analysis

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Electron impact dissociative excitation of O2: 2. Absolute emission cross sections of the OI(130.4 nm) and OI(135.6 nm) lines

Cited by 70 publications

References 41 publications

Polar cap arcs from the magnetosphere to the ionosphere: kinetic modelling and observations by Cluster and TIMED

Polar cap arcs from the magnetosphere to the ionosphere: kinetic modelling and observations by Cluster and TIMED

Orbital apocenter is not a sufficient condition for HST/STIS detection of Europa’s water vapor aurora

Laboratory studies of UV emissions from proton impact on N2: The Lyman-Birge-Hopfield band system for aurora analysis

Contact Info

Product

Resources

About

Electron impact dissociative excitation of O₂: 2. Absolute emission cross sections of the OI(130.4 nm) and OI(135.6 nm) lines

Laboratory studies of UV emissions from proton impact on N₂: The Lyman-Birge-Hopfield band system for aurora analysis