Patchy Proton Aurora at Mars: A Global View of Solar Wind Precipitation Across the Martian Dayside From EMM/EMUS

Michael S. Chaffin; Christopher M. Fowler; Justin Deighan; Sonal Jain; Greg Holsclaw; Andréa Hughes; Robin Ramstad; Yaxue Dong; Dave Brain; Hoor AlMazmi; Krishnaprasad Chirakkil; John Correira; Scott England; J. Scott Evans; Matt Fillingim; Rob Lillis; Fatma Lootah; Susarla Raghuram; Jim McFadden; Jasper Halekas; Jared Espley; Nick Schneider; Majd Mayyasi; Christina O. Lee; Shannon Curry; Hessa AlMatroushi

doi:10.1029/2022GL099881

Back

Patchy Proton Aurora at Mars: A Global View of Solar Wind Precipitation Across the Martian Dayside From EMM/EMUS

Journal article

Open access

Peer reviewed

Patchy Proton Aurora at Mars: A Global View of Solar Wind Precipitation Across the Martian Dayside From EMM/EMUS

Michael S. Chaffin, Christopher M. Fowler, Justin Deighan, Sonal Jain, Greg Holsclaw, Andréa Hughes, Robin Ramstad, Yaxue Dong, Dave Brain, Hoor AlMazmi, …

Geophysical research letters, Vol.49(17), e2022GL099881

09/16/2022

DOI: 10.1029/2022GL099881

Files and links (1)

url

https://doi.org/10.1029/2022GL099881View

Published (Version of record) Open Access

Abstract

Proton aurora at Mars are thought to form indirectly, as a result of solar wind proton charge exchange with planetary coronal hydrogen upstream of the bow shock. This charge exchange produces beamed energetic neutral atoms that bypass the induced magnetosphere and cause spatially uniform auroral emission when they collide with the thermosphere. Here we report multiple definitive observations of spatially localized “patchy” proton aurora at Mars using the Emirates Mars Ultraviolet Spectrometer on the Emirates Mars Mission, and characterize the plasma environment during these events using contemporaneous Mars Atmosphere and Volatile EvolutioN mission measurements. Multiple mechanisms are required to explain these observations, including at times the direct deposition of solar wind plasma into the thermosphere, particularly during radial interplanetary magnetic field conditions. Much future work will be needed to assess these mechanisms and understand the impact of these auroral events on Mars atmospheric evolution. Plain Language Summary Even though Mars does not have a global magnetic field like the Earth, it still possesses multiple kinds of aurora. One of these is proton aurora, which is thought to form mainly by an indirect process that allows a small fraction of the solar wind to rain down on the planet uniformly across the dayside. We present observations of patchy proton aurora at Mars that require a different explanation. By examining multiple Emirates Mars Mission observations of patchy aurora that have different shapes and locations, and combining these images with plasma measurements made by NASA's Mars Atmosphere and Volatile EvolutioN mission, we conclude that a number of processes can produce patchy aurora. This patchy aurora is mostly the result of plasma turbulence, which under some circumstances leads to direct deposition of the solar wind across the entire Martian dayside, with a potentially large impact on long term atmosphere and water loss from Mars. Key Points We present the first definitive evidence for spatially localized “patchy” proton aurora on Mars Some events support a hypothesis that radial interplanetary magnetic field conditions can produce patchy proton aurora Other events occur during typical solar wind conditions, requiring new formation mechanisms related to sheath plasma turbulence

aurora

Mars

radial IMF

Details

Title: Subtitle: Patchy Proton Aurora at Mars: A Global View of Solar Wind Precipitation Across the Martian Dayside From EMM/EMUS
Creators: Michael S. Chaffin - Laboratory for Atmospheric and Space Physics
Christopher M. Fowler - West Virginia University
Justin Deighan - Laboratory for Atmospheric and Space Physics
Sonal Jain - University of Colorado at Boulder
Greg Holsclaw - Laboratory for Atmospheric and Space Physics
Andréa Hughes - Goddard Space Flight Center
Robin Ramstad - Laboratory for Atmospheric and Space Physics
Yaxue Dong - Laboratory for Atmospheric and Space Physics
Dave Brain - University of Colorado at Boulder
Hoor AlMazmi - UAE Space Agency
Krishnaprasad Chirakkil - Khalifa University of Science and Technology
John Correira - Computational Physics (United States)
Scott England - Virginia Tech
J. Scott Evans - Computational Physics (United States)
Matt Fillingim - University of California, Berkeley
Rob Lillis - University of California, Berkeley
Fatma Lootah - Mohammed Bin Rashid Space Center Al Khawaneej United Arab Emirates
Susarla Raghuram - Laboratory for Atmospheric and Space Physics
Jim McFadden - University of California, Berkeley
Jasper Halekas - University of Iowa
Jared Espley - Goddard Space Flight Center
Nick Schneider - University of Colorado at Boulder
Majd Mayyasi - Boston University
Christina O. Lee - University of California, Berkeley
Shannon Curry - University of California, Berkeley
Hessa AlMatroushi - Mohammed Bin Rashid Space Center Al Khawaneej United Arab Emirates
Resource Type: Journal article
Publication Details: Geophysical research letters, Vol.49(17), e2022GL099881
DOI: 10.1029/2022GL099881
ISSN: 0094-8276
eISSN: 1944-8007
Number of pages: 11
Grant note: UAE government MBRSC MAVEN Space Science (8474000332‐KU‐CU‐LASP) NASA
Language: English
Date published: 09/16/2022
Academic Unit: Physics and Astronomy
Record Identifier: 9984428769002771

Metrics

10 Record Views

14 Times Cited - Web of Science

See more details