Description of Martian Convective Vortices Observed by InSight and Implications for Vertical Vortex Structure and Subsurface Physical Properties

Keisuke Onodera; Kiwamu Nishida; T Kawamura; Naomi Murdoch; Mélanie Drilleau; Ryoji Otsuka; Ralph Lorenz; Anna C Horleston; et al

doi:10.1029/2023JE007896

Description of Martian Convective Vortices Observed by InSight and Implications for Vertical Vortex Structure and Subsurface Physical Properties

Keisuke Onodera^*, Kiwamu Nishida, T Kawamura, Naomi Murdoch, Mélanie Drilleau, Ryoji Otsuka, Ralph Lorenz, Anna C Horleston, et al

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

6 Citations (Scopus)

Abstract

Convective vortices (whirlwinds) and dust devils (dust-loaded vortices) are one of the most common phenomena on Mars. They reflect the local thermodynamical structure of the atmosphere and are the driving force of the dust cycle. Additionally, they cause an elastic ground deformation, which is useful for retrieving the subsurface rigidity. Therefore, investigating convective vortices with the right instrumentation can lead to a better understanding of the Martian atmospheric structures as well as the subsurface physical properties. In this study, we quantitatively characterized the convective vortices detected by NASA's InSight (∼13,000 events) using meteorological (e.g., pressure, wind speed, temperature) and seismic data. The evaluated parameters, such as the signal-to-noise ratio, event duration, asymmetricity of pressure drop profiles, and cross-correlation between seismic and pressure signals, are compiled as a catalog. Using these parameters, we investigated (a) the vortex structure and (b) the subsurface physical properties. Regarding the first topic, we tried to illustrate the vertical vortex structure and its link to the shape of the pressure profiles by combining the asymmetrical features seen in the observed pressure drops and the terrestrial observations of dust devils. Our results indicate that most of the vortices move with the wall tilted in the advection direction. Concerning the second topic, selecting the highly correlated events between pressure perturbation and ground response, we estimated the subsurface rigidity at the InSight landing site down to 100 m depth. Our results indicate that the subsurface structure can be modeled with two layers having a transition at 5–15 m depth.

Original language	English
Article number	e2023JE007896
Number of pages	25
Journal	Journal of Geophysical Research: Planets
Volume	128
Issue number	8
DOIs	https://doi.org/10.1029/2023JE007896
Publication status	Published - 15 Aug 2023

Bibliographical note

Funding Information:
We acknowledge NASA, CNES, their partner agencies and Institutions (UKSA, SSO, DLR, JPL, IPGP-CNRS, ETHZ, IC, and MPS- MPG), and the flight operations team at JPL, SISMOC, MSDS, IRIS-DMC, and PDS for acquiring and providing InSight data, including SEED SEIS data. This is InSight contribution number 326. K.O. is supported by JSPS KAKENHI Grant 22KJ0745. A.H. is funded by the UK Space Agency under Grant ST/R002096/1 and ST/W002523/1. M.D. was granted access to the GENCI HPC resources of IDRIS under allocation AD010413017R1. Numerical computations were partly performed on the S-CAPAD/DANTE platform, IPGP, France. We would also like to show our gratitude to the editor (Dr. Laurent Montési), the associate editor (Dr. German Martinez), and two anonymous reviewers for giving us constructive advice, which made the manuscript more informative.

Funding Information:
We acknowledge NASA, CNES, their partner agencies and Institutions (UKSA, SSO, DLR, JPL, IPGP‐CNRS, ETHZ, IC, and MPS‐ MPG), and the flight operations team at JPL, SISMOC, MSDS, IRIS‐DMC, and PDS for acquiring and providing InSight data, including SEED SEIS data. This is InSight contribution number 326. K.O. is supported by JSPS KAKENHI Grant 22KJ0745. A.H. is funded by the UK Space Agency under Grant ST/R002096/1 and ST/W002523/1. M.D. was granted access to the GENCI HPC resources of IDRIS under allocation AD010413017R1. Numerical computations were partly performed on the S‐CAPAD/DANTE platform, IPGP, France. We would also like to show our gratitude to the editor (Dr. Laurent Montési), the associate editor (Dr. German Martinez), and two anonymous reviewers for giving us constructive advice, which made the manuscript more informative.

Publisher Copyright:
© 2023. The Authors.

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10.1029/2023JE007896Licence: CC BY-NC-ND

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Exploring the Seismicity of Mars with InSight (YR1)
Teanby, N. A. (Principal Investigator)
1/04/21 → 31/03/23
Project: Research
Exploring the Seismicity of Mars with InSight (YR2+YR3)
Teanby, N. A. (Principal Investigator)
1/04/21 → 31/03/22
Project: Research, Parent
Mars' crustal structure and seismic environment from NASA/InSight (updated for 1/4/2018 start)
Teanby, N. A. (Principal Investigator)
1/04/18 → 31/03/22
Project: Research

Cite this

Onodera, K., Nishida, K., Kawamura, T., Murdoch, N., Drilleau, M., Otsuka, R., Lorenz, R., Horleston, A. C., & al, E. (2023). Description of Martian Convective Vortices Observed by InSight and Implications for Vertical Vortex Structure and Subsurface Physical Properties. Journal of Geophysical Research: Planets, 128(8), Article e2023JE007896. https://doi.org/10.1029/2023JE007896

@article{689963bd4a3e4e31aff832b81e49dda4,

title = "Description of Martian Convective Vortices Observed by InSight and Implications for Vertical Vortex Structure and Subsurface Physical Properties",

abstract = "Convective vortices (whirlwinds) and dust devils (dust-loaded vortices) are one of the most common phenomena on Mars. They reflect the local thermodynamical structure of the atmosphere and are the driving force of the dust cycle. Additionally, they cause an elastic ground deformation, which is useful for retrieving the subsurface rigidity. Therefore, investigating convective vortices with the right instrumentation can lead to a better understanding of the Martian atmospheric structures as well as the subsurface physical properties. In this study, we quantitatively characterized the convective vortices detected by NASA's InSight (∼13,000 events) using meteorological (e.g., pressure, wind speed, temperature) and seismic data. The evaluated parameters, such as the signal-to-noise ratio, event duration, asymmetricity of pressure drop profiles, and cross-correlation between seismic and pressure signals, are compiled as a catalog. Using these parameters, we investigated (a) the vortex structure and (b) the subsurface physical properties. Regarding the first topic, we tried to illustrate the vertical vortex structure and its link to the shape of the pressure profiles by combining the asymmetrical features seen in the observed pressure drops and the terrestrial observations of dust devils. Our results indicate that most of the vortices move with the wall tilted in the advection direction. Concerning the second topic, selecting the highly correlated events between pressure perturbation and ground response, we estimated the subsurface rigidity at the InSight landing site down to 100 m depth. Our results indicate that the subsurface structure can be modeled with two layers having a transition at 5–15 m depth.",

author = "Keisuke Onodera and Kiwamu Nishida and T Kawamura and Naomi Murdoch and M{\'e}lanie Drilleau and Ryoji Otsuka and Ralph Lorenz and Horleston, \{Anna C\} and et al",

note = "Funding Information: We acknowledge NASA, CNES, their partner agencies and Institutions (UKSA, SSO, DLR, JPL, IPGP-CNRS, ETHZ, IC, and MPS- MPG), and the flight operations team at JPL, SISMOC, MSDS, IRIS-DMC, and PDS for acquiring and providing InSight data, including SEED SEIS data. This is InSight contribution number 326. K.O. is supported by JSPS KAKENHI Grant 22KJ0745. A.H. is funded by the UK Space Agency under Grant ST/R002096/1 and ST/W002523/1. M.D. was granted access to the GENCI HPC resources of IDRIS under allocation AD010413017R1. Numerical computations were partly performed on the S-CAPAD/DANTE platform, IPGP, France. We would also like to show our gratitude to the editor (Dr. Laurent Mont{\'e}si), the associate editor (Dr. German Martinez), and two anonymous reviewers for giving us constructive advice, which made the manuscript more informative. Funding Information: We acknowledge NASA, CNES, their partner agencies and Institutions (UKSA, SSO, DLR, JPL, IPGP‐CNRS, ETHZ, IC, and MPS‐ MPG), and the flight operations team at JPL, SISMOC, MSDS, IRIS‐DMC, and PDS for acquiring and providing InSight data, including SEED SEIS data. This is InSight contribution number 326. K.O. is supported by JSPS KAKENHI Grant 22KJ0745. A.H. is funded by the UK Space Agency under Grant ST/R002096/1 and ST/W002523/1. M.D. was granted access to the GENCI HPC resources of IDRIS under allocation AD010413017R1. Numerical computations were partly performed on the S‐CAPAD/DANTE platform, IPGP, France. We would also like to show our gratitude to the editor (Dr. Laurent Mont{\'e}si), the associate editor (Dr. German Martinez), and two anonymous reviewers for giving us constructive advice, which made the manuscript more informative. Publisher Copyright: {\textcopyright} 2023. The Authors.",

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month = aug,

day = "15",

doi = "10.1029/2023JE007896",

language = "English",

volume = "128",

journal = "Journal of Geophysical Research: Planets",

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Onodera, K, Nishida, K, Kawamura, T, Murdoch, N, Drilleau, M, Otsuka, R, Lorenz, R, Horleston, AC & al, E 2023, 'Description of Martian Convective Vortices Observed by InSight and Implications for Vertical Vortex Structure and Subsurface Physical Properties', Journal of Geophysical Research: Planets, vol. 128, no. 8, e2023JE007896. https://doi.org/10.1029/2023JE007896

Description of Martian Convective Vortices Observed by InSight and Implications for Vertical Vortex Structure and Subsurface Physical Properties. / Onodera, Keisuke; Nishida, Kiwamu; Kawamura, T et al.
In: Journal of Geophysical Research: Planets, Vol. 128, No. 8, e2023JE007896, 15.08.2023.

Research output: Contribution to journal › Article (Academic Journal) › peer-review

TY - JOUR

T1 - Description of Martian Convective Vortices Observed by InSight and Implications for Vertical Vortex Structure and Subsurface Physical Properties

AU - Onodera, Keisuke

AU - Nishida, Kiwamu

AU - Kawamura, T

AU - Murdoch, Naomi

AU - Drilleau, Mélanie

AU - Otsuka, Ryoji

AU - Lorenz, Ralph

AU - Horleston, Anna C

AU - al, et

N1 - Funding Information: We acknowledge NASA, CNES, their partner agencies and Institutions (UKSA, SSO, DLR, JPL, IPGP-CNRS, ETHZ, IC, and MPS- MPG), and the flight operations team at JPL, SISMOC, MSDS, IRIS-DMC, and PDS for acquiring and providing InSight data, including SEED SEIS data. This is InSight contribution number 326. K.O. is supported by JSPS KAKENHI Grant 22KJ0745. A.H. is funded by the UK Space Agency under Grant ST/R002096/1 and ST/W002523/1. M.D. was granted access to the GENCI HPC resources of IDRIS under allocation AD010413017R1. Numerical computations were partly performed on the S-CAPAD/DANTE platform, IPGP, France. We would also like to show our gratitude to the editor (Dr. Laurent Montési), the associate editor (Dr. German Martinez), and two anonymous reviewers for giving us constructive advice, which made the manuscript more informative. Funding Information: We acknowledge NASA, CNES, their partner agencies and Institutions (UKSA, SSO, DLR, JPL, IPGP‐CNRS, ETHZ, IC, and MPS‐ MPG), and the flight operations team at JPL, SISMOC, MSDS, IRIS‐DMC, and PDS for acquiring and providing InSight data, including SEED SEIS data. This is InSight contribution number 326. K.O. is supported by JSPS KAKENHI Grant 22KJ0745. A.H. is funded by the UK Space Agency under Grant ST/R002096/1 and ST/W002523/1. M.D. was granted access to the GENCI HPC resources of IDRIS under allocation AD010413017R1. Numerical computations were partly performed on the S‐CAPAD/DANTE platform, IPGP, France. We would also like to show our gratitude to the editor (Dr. Laurent Montési), the associate editor (Dr. German Martinez), and two anonymous reviewers for giving us constructive advice, which made the manuscript more informative. Publisher Copyright: © 2023. The Authors.

PY - 2023/8/15

Y1 - 2023/8/15

N2 - Convective vortices (whirlwinds) and dust devils (dust-loaded vortices) are one of the most common phenomena on Mars. They reflect the local thermodynamical structure of the atmosphere and are the driving force of the dust cycle. Additionally, they cause an elastic ground deformation, which is useful for retrieving the subsurface rigidity. Therefore, investigating convective vortices with the right instrumentation can lead to a better understanding of the Martian atmospheric structures as well as the subsurface physical properties. In this study, we quantitatively characterized the convective vortices detected by NASA's InSight (∼13,000 events) using meteorological (e.g., pressure, wind speed, temperature) and seismic data. The evaluated parameters, such as the signal-to-noise ratio, event duration, asymmetricity of pressure drop profiles, and cross-correlation between seismic and pressure signals, are compiled as a catalog. Using these parameters, we investigated (a) the vortex structure and (b) the subsurface physical properties. Regarding the first topic, we tried to illustrate the vertical vortex structure and its link to the shape of the pressure profiles by combining the asymmetrical features seen in the observed pressure drops and the terrestrial observations of dust devils. Our results indicate that most of the vortices move with the wall tilted in the advection direction. Concerning the second topic, selecting the highly correlated events between pressure perturbation and ground response, we estimated the subsurface rigidity at the InSight landing site down to 100 m depth. Our results indicate that the subsurface structure can be modeled with two layers having a transition at 5–15 m depth.

AB - Convective vortices (whirlwinds) and dust devils (dust-loaded vortices) are one of the most common phenomena on Mars. They reflect the local thermodynamical structure of the atmosphere and are the driving force of the dust cycle. Additionally, they cause an elastic ground deformation, which is useful for retrieving the subsurface rigidity. Therefore, investigating convective vortices with the right instrumentation can lead to a better understanding of the Martian atmospheric structures as well as the subsurface physical properties. In this study, we quantitatively characterized the convective vortices detected by NASA's InSight (∼13,000 events) using meteorological (e.g., pressure, wind speed, temperature) and seismic data. The evaluated parameters, such as the signal-to-noise ratio, event duration, asymmetricity of pressure drop profiles, and cross-correlation between seismic and pressure signals, are compiled as a catalog. Using these parameters, we investigated (a) the vortex structure and (b) the subsurface physical properties. Regarding the first topic, we tried to illustrate the vertical vortex structure and its link to the shape of the pressure profiles by combining the asymmetrical features seen in the observed pressure drops and the terrestrial observations of dust devils. Our results indicate that most of the vortices move with the wall tilted in the advection direction. Concerning the second topic, selecting the highly correlated events between pressure perturbation and ground response, we estimated the subsurface rigidity at the InSight landing site down to 100 m depth. Our results indicate that the subsurface structure can be modeled with two layers having a transition at 5–15 m depth.

U2 - 10.1029/2023JE007896

DO - 10.1029/2023JE007896

M3 - Article (Academic Journal)

SN - 2169-9097

VL - 128

JO - Journal of Geophysical Research: Planets

JF - Journal of Geophysical Research: Planets

IS - 8

M1 - e2023JE007896

ER -

Description of Martian Convective Vortices Observed by InSight and Implications for Vertical Vortex Structure and Subsurface Physical Properties

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Projects

Exploring the Seismicity of Mars with InSight (YR1)

Exploring the Seismicity of Mars with InSight (YR2+YR3)

Mars' crustal structure and seismic environment from NASA/InSight (updated for 1/4/2018 start)

Cite this