Simulation of the 2018 Global Dust Storm on Mars Using the NASA Ames Mars GCM: A Multi-Tracer Approach
Tanguy Bertrand, R. John Wilson, Melinda A. Kahre, Richard Urata and, Alex Kling

TL;DR
This study models the 2018 global dust storm on Mars using the NASA Ames Mars GCM, revealing insights into dust transport, atmospheric circulation, and cloud dynamics during the storm.
Contribution
It introduces a multi-tracer approach with the NASA Ames Mars GCM to simulate and analyze the evolution of the 2018 Martian dust storm.
Findings
Rapid eastward dust transport and lifting in equatorial regions
Enhanced Hadley cell circulation during the storm
Dust plumes reaching up to 80 km altitude
Abstract
Global dust storms are the most thermodynamically significant dust events on Mars. They are produced from the combination of multiple local and regional lifting events and maintained by positive radiative-dynamic feedbacks. The most recent of these events, which began in June 2018, was monitored by several spacecraft in orbit and on the surface, but many questions remain regarding its onset, expansion and decay. We model the 2018 global dust storm with the NASA Ames Mars Global Climate Model to better understand the evolution of the storm and how the general circulation and finite surface dust reservoirs impact it. The global dust storm is characterized by the rapid eastward transport of dust in the equatorial regions and subsequent lifting. We highlight the rapid transfer of dust between western and eastern hemispheres reservoirs, which may play an important role in the storm…
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Taxonomy
TopicsPlanetary Science and Exploration · Space exploration and regulation · Spaceflight effects on biology
