Sub‐Diurnal Methane Variations on Mars Driven by Barometric Pumping and Planetary Boundary Layer Evolution

In recent years, the Tunable Laser Spectrometer within the Sample Analysis at Mars (TLS‐SAM) instrument on board the Mars Science Laboratory (MSL) Curiosity rover has detected methane variations in the atmosphere at Gale crater. Methane concentrations appear to fluctuate seasonally as well as sub‐di...

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Bibliographic Details
Published in:Journal of geophysical research. Planets 2024-01, Vol.129 (1), p.n/a
Main Authors: Ortiz, J. P., Rajaram, H., Stauffer, P. H., Lewis, K. W., Wiens, R. C., Harp, D. R.
Format: Article
Language:English
Subjects:
Abundance
Adsorption
Atmosphere
Atmospheric methane
Atmospheric mixing
Atmospheric pressure
Barometers
barometric pumping
Boundary layer evolution
Boundary layers
Curiosity (Mars rover)
Diurnal variations
ENVIRONMENTAL SCIENCES
Fluctuations
fractures
Mars
Mars atmosphere
Mars craters
Mars missions
Mars surface
Methane
Methane emissions
Planetary boundary layer
planetary boundary layer (PBL)
Planetary evolution
Pressure fluctuations
Pumping
Rocks
Sampling
Seasonal variations
Seepage
Simulation
Summer
Sunrise
Surface chemistry
Temperature dependence
tracer flow & transport
Tunable lasers
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Summary:In recent years, the Tunable Laser Spectrometer within the Sample Analysis at Mars (TLS‐SAM) instrument on board the Mars Science Laboratory (MSL) Curiosity rover has detected methane variations in the atmosphere at Gale crater. Methane concentrations appear to fluctuate seasonally as well as sub‐diurnally, which is difficult to reconcile with an as‐yet‐unknown transport mechanism delivering the gas from underground to the atmosphere. To potentially explain the fluctuations, we consider barometrically induced transport of methane from an underground source to the surface, modulated by temperature‐dependent adsorption. The subsurface fractured‐rock seepage model is coupled to a simplified 1‐D atmospheric mixing model to provide insights on the pattern of atmospheric methane concentrations in response to transient surface methane emissions, as well as to predict sub‐diurnal variation in methane abundance for the northern summer period, which is a candidate time frame for a MSL Curiosity sampling campaign. Our analysis suggests that there is a lower limit to the subsurface fracture density that can produce the observed methane patterns, below which the atmospheric methane variations would be out of phase with the observations. The best‐performing model scenarios indicate a significant, short‐lived methane pulse just prior to sunrise, the detection of which by TLS‐SAM would be a potential indicator of the contribution of barometric pumping to Mars' atmospheric methane variations. Plain Language Summary One of the outstanding goals of current Mars missions is to detect and understand biosignatures (signs of ancient or present life, if they exist) such as methane. Methane has been detected multiple times in Mars' atmosphere close to the planet's surface by the Mars Science Laboratory (MSL) Curiosity rover, and its abundance appears to fluctuate seasonally and on a daily time scale. With the source of methane on Mars most likely located underground, it is difficult to reconcile these atmospheric variations with an as‐yet‐unknown transport mechanism delivering the gas to the atmosphere. In this manuscript, we simulate methane transport to the atmosphere from underground fractured rock driven by atmospheric pressure fluctuations. We also model adsorption of methane molecules onto the surface of pores in the rock, which is a temperature‐dependent process that may contribute to the apparent seasonality of methane abundance. We simulated methane emitted from the subsu
ISSN:2169-9097
2169-9100
DOI:10.1029/2023JE008043