Explanation for the Increase in High‐Altitude Water on Mars Observed by NOMAD During the 2018 Global Dust Storm

Neary, L.; Daerden, Frank; Aoki, Shohei; Whiteway, J. A.; Clancy, R. T.; Smith, M. D.; Viscardy, S.; Erwin, Justin; Thomas, Ian; Villanueva, Gerónimo; Liuzzi, Giuliano; Crismani, Matteo; Wolff, Michael; Lewis, S. R.; Holmes, James; Patel, Manish R.; Giuranna, M.; Depiesse, C.; Piccialli, Arianna; Robert, Séverine; Trompet, Loïc; Willame, Yannick; Ristić, Bojan; Vandaele, Ann Carine

doi:10.1029/2019gl084354

Cited by 71 publications

(109 citation statements)

References 32 publications

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“…Moreover, peak cloud altitudes are slightly higher during the onset of the GDS than reported in non‐GDS years. Indeed, models (Neary et al, ) showed that GDSs are expected to slightly increase the average and maximum altitude of water ice clouds, which is consistent with our observations. The sharp increase in water ice cloud altitude observed during the GDS indeed confirms that this water ice cloud increase is directly connected to dust storm activity.…”

Section: Resultssupporting

confidence: 92%

“…We note that the above behavior appears to be relatively uniform around the planet (i.e., both zonally and meridionally). Specifically, in the southern hemisphere, even though the observed latitude varies from 74

S to 5

S between

L_{s} = 21 9^{\circ}

and

L_{s} = 24 1^{\circ}

, one does not see a change in both the haze top altitude and the maximal altitude of the water ice clouds; in agreement with the simulations presented in Neary et al (, Figure ). We nonetheless identify a temporal trend likely related to the progressive decay of the dust storm (Guzewich et al, ): From

L_{s} = 22 0^{\circ}

L_{s} = 24 3^{\circ}

, the lower altitude of the detected water ice clouds in the southern hemisphere decreases from 68 to 54 km (cf.…”

Section: Resultssupporting

confidence: 90%

“…The large-scale dust storm probably facilitates the formation of high-altitude water ice clouds through increase in the altitude of both water vapor and condensation nuclei. This increase of water ice altitude during the GDS is indeed consistent with the recently reported increase of water vapor at higher altitudes Neary et al, 2019). Note.…”

Section: During the Gds (L S > 200 • )supporting

confidence: 91%

“…Recent studies have notably reveal how more precise vertical representation of water-related atmospheric phenomena may impact water cycle modeling The MY 28 dust storm has been shown to have profoundly influenced the water vapor atmospheric distribution, elevating water well above the troposphere (>60 km) while pushing up the hygropause altitude (Heavens et al, 2018). A rapid increase of the H 2 O and HDO abundances at altitudes between 40 and 80 km was observed during MY 34 storm and recently reproduced in a GCM simulation (Neary et al, 2019). This large augmentation of the high-altitude water content is believed to boost hydrogen, or nearly equivalently, water escape from Mars Fedorova et al, 2020;Heavens et al, 2018).…”

Section: Introductionmentioning

confidence: 95%

“…However, the formation of clouds impacts the ability of water (or hydrogen) to escape as it confines (in theory) a significant fraction of water below the cloud level. Thus, understanding the extent to which high-altitude water vapor condenses to form clouds during GDSs is important in assessing the possible propagation pathways of water vapor up to the exobase (Neary et al, 2019). Because water vapor can exist in a supersaturated state in the Martian atmosphere (Maltagliati et al, 2011) and has been observed in a large amount during the MY 34 GDS (Fedorova et al, 2020), simply supposing that the freezing point can be used to set the limits where water is free to be mobilized, is likely to be problematic.…”

Section: Introductionmentioning

confidence: 99%

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Martian Water Ice Clouds During the 2018 Global Dust Storm as Observed by the ACS‐MIR Channel Onboard the Trace Gas Orbiter

et al. 2020

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The Atmospheric Chemistry Suite (ACS) instrument onboard the ExoMars Trace Gas Orbiter (TGO) European Space Agency‐Roscosmos mission began science operations in March 2018. ACS Mid‐InfraRed (MIR) channel notably provides solar occultation observations of the Martian atmosphere in the 2.3‐ to 4.2‐ normalμ m spectral range. Here, we use these observations to characterize water ice clouds before and during the MY 34 Global Dust Storm (GDS). We developed a method to detect water ice clouds with mean particle size ≤ 2 normalμ m and applied it to observations gathered between Ls=165∘ and Ls=243∘. We observe a shift in water ice cloud maximum altitudes from about 60 km before the GDS to above 90 km during the storm. These very high altitude, small‐sized ( reff≤0.3.3emnormalμ m) water ice clouds are more frequent during MY 34 compared to non‐GDS years at the same season. Particle size frequently decreases with altitude, both locally within a given profile and globally in the whole data set. We observe that the maximum altitude at which a given size is observed can increase during the GDS by several tens of kilometers for certain sizes. We notably notice some large water ice particles ( reff≥1.5.3emnormalμ m) at surprisingly high altitudes during the GDS (50–70 km). These results suggest that GDS can significantly impact the formation and properties of high‐altitude water ice clouds as compared to the usual perihelion dust activity.

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Section: Resultssupporting

confidence: 92%

S to 5

S between

L_{s} = 21 9^{\circ}

and

L_{s} = 24 1^{\circ}

L_{s} = 22 0^{\circ}

L_{s} = 24 3^{\circ}

, the lower altitude of the detected water ice clouds in the southern hemisphere decreases from 68 to 54 km (cf.…”

Section: Resultssupporting

confidence: 90%

Section: During the Gds (L S > 200 • )supporting

confidence: 91%

Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

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Martian Water Ice Clouds During the 2018 Global Dust Storm as Observed by the ACS‐MIR Channel Onboard the Trace Gas Orbiter

et al. 2020

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The high-altitude peaks of atmospheric ozone as observed by NOMAD/UVIS onboard the ExoMars Trace Gas Orbiter Mission

Khayat

Smith

Wolff

et al. 2021

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Vertical aerosol distribution and mesospheric clouds from ExoMars UVIS

Streeter

Sellers

Wolff

et al. 2021

Preprint

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Suspended atmospheric aerosols are key components of the martian atmosphere, and their vertical distribution has long been a subject of investigation with orbital observations and modeling. The aerosols found in Mars' atmosphere are mineral dust, water ice, and CO 2 ice, and each have distinct spatiotemporal distributions and radiative effects. Early analytical calculations based on estimated dust sedimentation and diffusion rates alongside orbital observations of a Global Dust Storm (GDS) led to the development of a standard dust profile often used

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Explanation for the Increase in High‐Altitude Water on Mars Observed by NOMAD During the 2018 Global Dust Storm

Cited by 71 publications

References 32 publications

Martian Water Ice Clouds During the 2018 Global Dust Storm as Observed by the ACS‐MIR Channel Onboard the Trace Gas Orbiter

Martian Water Ice Clouds During the 2018 Global Dust Storm as Observed by the ACS‐MIR Channel Onboard the Trace Gas Orbiter

The high-altitude peaks of atmospheric ozone as observed by NOMAD/UVIS onboard the ExoMars Trace Gas Orbiter Mission

Vertical aerosol distribution and mesospheric clouds from ExoMars UVIS

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