Hot oxygen corona at Mars and the photochemical escape of oxygen: Improved description of the thermosphere, ionosphere, and exosphere

Lee, Yuni; Combi, M. R.; Tenishev, V.; Bougher, S. W.; Lillis, R. J.

doi:10.1002/2015je004890

Cited by 46 publications

(103 citation statements)

References 38 publications

(108 reference statements)

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“…Basically, the hot oxygen has a thermal speed larger than the local background thermal speed (calculated based on M-GITM thermospheric profile [Bougher et al, 2015]), indicating the scale height of hot oxygen is larger than that of the cold oxygen [e.g., Ma et al, 2004, Figures 1 and 2]. However, the hot oxygen can be converted to the thermal oxygen via collisions with other background cold neutral species before it escapes to interplanetary space [Lee et al, 2013]. It is noteworthy that when we mention the cold heavy ionospheric molecular/atomic ions, it refers to those ionized from the cold molecular/atomic neutrals.…”

Section: Introductionmentioning

confidence: 99%

“…The MF-MHD code solves separate continuity, momentum, and energy equations for each ion species [Powell et al, 1999;Glocer et al, 2009;Najib et al, 2011;Tóth et al, 2012;Dong et al, 2014]. Please refer to Lee et al [2013Lee et al [ , 2014aLee et al [ , 2014b for the detailed study of one-way coupling between M-GITM and M-AMPS (as indicated by the dashed line in Figure 1); i.e., M-GITM provides thermosphere/ionosphere background as an input into the M-AMPS exosphere model. These calculations are carried out for 22 cases with combinations of different crustal field orientations (four cases without crustal field), solar cycle, and Martian seasonal conditions.…”

Section: Introductionmentioning

confidence: 99%

“…Here we focus on the one-way coupling indicated by the solid line. For the detailed study of one-way coupling between M-GITM and M-AMPS (dashed line), please refer to Lee et al [2013Lee et al [ , 2014aLee et al [ , 2014b.…”

Section: Introductionmentioning

confidence: 99%

“…In order to reproduce a realistic asymmetric corona of hot species from observations, a 3-D global kinetic exosphere model is required, especially above the exobase (Knudsen number, K n ≈ 1) where the fluid assumption usually fails [Lee et al, 2013]. One such model is the Mars exosphere Monte Carlo model Adaptive Mesh Particle Simulator (M-AMPS) [Tenishev and Combi, 2008;Lee et al, 2013Lee et al, , 2014aLee et al, , 2014b, which can generate a 3-D hot (e.g., oxygen and carbon) corona with detailed asymmetric structure. In order to capture these 3-D asymmetries, 3-D thermosphere/ionosphere inputs from a validated ground-to-exobase atmospheric model (e.g., M-GITM) are essential (see Figure 1 for more detail).…”

Section: Introductionmentioning

confidence: 99%

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Solar wind interaction with the Martian upper atmosphere: Crustal field orientation, solar cycle, and seasonal variations

Dong

Bougher

et al. 2015

JGR Space Physics

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A comprehensive study of the solar wind interaction with the Martian upper atmosphere is presented. Three global models: the 3‐D Mars multifluid Block Adaptive Tree Solar‐wind Roe Upwind Scheme MHD code (MF‐MHD), the 3‐D Mars Global Ionosphere Thermosphere Model (M‐GITM), and the Mars exosphere Monte Carlo model Adaptive Mesh Particle Simulator (M‐AMPS) were used in this study. These models are one‐way coupled; i.e., the MF‐MHD model uses the 3‐D neutral inputs from M‐GITM and the 3‐D hot oxygen corona distribution from M‐AMPS. By adopting this one‐way coupling approach, the Martian upper atmosphere ion escape rates are investigated in detail with the combined variations of crustal field orientation, solar cycle, and Martian seasonal conditions. The calculated ion escape rates are compared with Mars Express observational data and show reasonable agreement. The variations in solar cycles and seasons can affect the ion loss by a factor of ∼3.3 and ∼1.3, respectively. The crustal magnetic field has a shielding effect to protect Mars from solar wind interaction, and this effect is the strongest for perihelion conditions, with the crustal field facing the Sun. Furthermore, the fraction of cold escaping heavy ionospheric molecular ions [( and/or )/Total] are inversely proportional to the fraction of the escaping (ionospheric and corona) atomic ion [O+/Total], whereas and ion escape fractions show a positive linear correlation since both ion species are ionospheric ions that follow the same escaping path.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Solar wind interaction with the Martian upper atmosphere: Crustal field orientation, solar cycle, and seasonal variations

Dong

Bougher

et al. 2015

JGR Space Physics

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“…Several hot O transport models have been constructed to simulate this, including two-stream, Monte Carlo, and DSMC (Direct Simulation Monte Carlo) models [e.g., Nagy and Cravens, 1988;Ip, 1990;Kim et al, 1998;Hodges, 2000;Hać, 2009, 2014;Valeille et al, 2009aValeille et al, , 2009bValeille et al, , 2010aValeille et al, , 2010bYagi et al, 2012;Lee et al, 2013;Gröller et al, 2014]. But these photochemical escape rate calculations vary by about 2 orders of magnitude as summarized in Table 3 of Fox and Hać [2009], and there is a lack of direct observational constraint on photochemical escape models.…”

Section: Introductionmentioning

confidence: 99%

Pickup ion measurements by MAVEN: A diagnostic of photochemical oxygen escape from Mars

Rahmati

Cravens

Nagy

et al. 2014

Geophysical Research Letters

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A key process populating the oxygen exosphere at Mars is the dissociative recombination of ionospheric O 2 + , which produces fast oxygen atoms, some of which have speeds exceeding the escape speed and thus contribute to atmospheric loss. Theoretical studies of this escape process have been carried out and predictions made of the loss rate; however, directly measuring the escaping neutral oxygen is difficult but essential. This paper describes how energetic pickup ion measurements to be made near Mars by the SEP (Solar Energetic Particle) instrument on board the MAVEN (Mars Atmosphere and Volatile EvolutioN) spacecraft can be used to constrain models of photochemical oxygen escape. In certain solar wind conditions, neutral oxygen atoms in the distant Martian exosphere that are ionized and picked up by the solar wind can reach energies high enough to be detected near Mars by SEP.

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A full‐particle Martian upper thermosphere‐exosphere model using the DSMC method

Terada

Shinagawa

et al. 2016

JGR Planets

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International audienceA one-dimensional full-particle model of the Martian upper thermosphere-exosphere has been developed, where the Direct Simulation Monte Carlo (DSMC) method is applied to both thermal and non-thermal components. Our full-particle model can self-consistently solve the transition from collisional to collisionless domains in the upper thermosphere, so that the energy deposition from non-thermal energetic components to thermal components in the transition region is properly described. For the solar EUV condition during the Viking-1 measurement (1 EUV case), computed density profiles are in good agreement with those observed by Viking 1 and with the conventional model. For a solar EUV flux six times the Viking-1 condition (6 EUV case), the computed heating efficiency is essentially the same as 1 EUV case but slightly increases by about 10 % below the exobase, and temperature deviates from the conventional model in and above the transition region. This result suggests that the conventional heating efficiency of 0.18 is a good approximation for low (1 EUV case) to moderately strong (6 EUV case) solar EUV conditions but would be inappropriate for an extremely strong solar EUV (up to ~100 times stronger flux) environment. We also find that applying different models of the CO2-O collisional energy transfer rate results in a difference in the calculated exobase temperature by 150 K for 6 EUV case

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Hot oxygen corona at Mars and the photochemical escape of oxygen: Improved description of the thermosphere, ionosphere, and exosphere

Cited by 46 publications

References 38 publications

Solar wind interaction with the Martian upper atmosphere: Crustal field orientation, solar cycle, and seasonal variations

Solar wind interaction with the Martian upper atmosphere: Crustal field orientation, solar cycle, and seasonal variations

Pickup ion measurements by MAVEN: A diagnostic of photochemical oxygen escape from Mars

A full‐particle Martian upper thermosphere‐exosphere model using the DSMC method

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