Details

Autor(en) / Beteiligte

• Lillis, Robert J.
• Deighan, Justin
• Fox, Jane L.
• Bougher, Stephen W.
• Lee, Yuni
• Combi, Michael R.
• Cravens, Thomas E.
• Rahmati, Ali
• Mahaffy, Paul R.
• Benna, Mehdi
• Elrod, Meredith K.
• McFadden, James P.
• Ergun, Robert. E.
• Andersson, Laila
• Fowler, Christopher M.
• Jakosky, Bruce M.
• Thiemann, Ed
• Eparvier, Frank
• Halekas, Jasper S.
• Leblanc, François
• Chaufray, Jean‐Yves

Titel

Photochemical escape of oxygen from Mars: First results from MAVEN in situ data

Ist Teil von

• Journal of geophysical research. Space physics, 2017-03, Vol.122 (3), p.3815-3836

Ort / Verlag

Washington: Blackwell Publishing Ltd

Erscheinungsjahr

2017

Quelle

Wiley Online Library

Beschreibungen/Notizen

• Photochemical escape of atomic oxygen is thought to be one of the dominant channels for Martian atmospheric loss today and played a potentially major role in climate evolution. Mars Atmosphere and Volatile Evolution Mission (MAVEN) is the first mission capable of measuring, in situ, the relevant quantities necessary to calculate photochemical escape fluxes. We utilize 18 months of data from three MAVEN instruments: Langmuir Probe and Waves, Neutral Gas and Ion Mass Spectrometer, and SupraThermal And Thermal Ion Composition. From these data, we calculate altitude profiles of the production rate of hot oxygen atoms from the dissociative recombination of O2+ and the probability that such atoms will escape the Mars atmosphere. From this, we determine escape fluxes for 815 periapsis passes. Derived average dayside hot O escape rates range from 1.2 to 5.5 × 1025 s−1, depending on season and EUV flux, consistent with several pre‐MAVEN predictions and in broad agreement with estimates made with other MAVEN measurements. Hot O escape fluxes do not vary significantly with dayside solar zenith angle or crustal magnetic field strength but depend on CO2 photoionization frequency with a power law whose exponent is 2.6 ± 0.6, an unexpectedly high value which may be partially due to seasonal and geographic sampling. From this dependence and historical EUV measurements over 70 years, we estimate a modern‐era average escape rate of 4.3 × 1025 s−1. Extrapolating this dependence to early solar system, EUV conditions gives total losses of 13, 49, 189, and 483 mbar of oxygen over 1–3 and 3.5 Gyr, respectively, with uncertainties significantly increasing with time in the past. Key Points Photochemical O escape fluxes from dissociative recombination of O2+ are calculated from MAVEN in situ data Escape rates of 1.2 to 5.5 × 1025 s−1 are derived and depend on season, solar zenith angle, and EUV flux, consistent with previous models We find a power law exponent of 2.6 for the EUV dependence of escape rate, implying 100 s of mbar of oxygen loss over 3.5 Gyr