Knowledge of Mars’ weather will also help with planning future NASA missions, said Greybush.
“If we can learn more about the atmospheric conditions of Mars, we may be able to land in more interesting places, such as those with hills and craters rather than flat terrain,” Greybush said.
Greybush is working on a tool called Ensemble Mars Atmosphere Reanalysis System (EMARS). The system takes measurements received from orbiting spacecraft, such as temperature or dust, and combines the information with computer simulations using a process called data assimilation. EMARS creates a sequence of maps of winds, temperatures, pressures and dust at hourly intervals over six Martian years. A Mars year is 687 Earth days.
With this information, Greybush can follow the evolution of dust storms and track how they grow from a local-scale dust storm to planetary scale.
Along with tracking the storms, Greybush can use EMARS to compare the current dust storm to previous storms. This method yields important insights into the variability of Mars’ weather patterns over time.
Greybush hopes EMARS will assist other researchers in their study of the planet and help explore the predictability of traveling weather systems and dust storms. When speaking of traveling weather systems, Mars has seasons, pressure systems and weather fronts, much like Earth.
Studying these dust storms and the weather on Mars may also assist in the study of Earth. Greybush said that traveling weather systems in the mid-latitude on Mars resemble those in the mid-latitudes on Earth.
Hartzel Gillespie, a doctoral graduate student in meteorology working with Greybush, studies the traveling weather systems of Mars. Gillespie said that there are hypotheses that the winds of the weather systems may cause the formation of these dust storms.
“The current Martian dust storm will provide an interesting case study for that hypothesis,” Gillespie said. “It would be quite interesting if we were able, in the future, to show that this dust storm was caused by a particular traveling weather system.”
Local and regional storms take place on Mars yearly, but estimates say that global storms occur once every three or four Martian years, which is six to eight Earth years.
Global storms can occur from intense winds lifting the dust off of the ground — sometimes up to 24 miles in altitude. As dust is carried higher into the atmosphere, it gets caught in faster winds and can be moved across the planet. It can take up to several weeks for the dust to settle.
“A lot of storms begin in the northern hemisphere and then fizzle out, so why did this northern storm make it past the equator and become so large?” Greybush asked. “The last global storm was in 2007. Each storm is unique, and this provides a new example for case studies.”
Mars is the planet that is most like Earth, as it shares similar characteristics and history, but the stark differences, such as the nature of its extreme weather, are what researchers are aiming to understand.
“People ask why we study Mars’ weather and the simple answer is scientific curiosity,” Greybush said. “We want to know what storms and weather are like on other planets. Are they similar or are they different? These dust storms give us data and insight into these processes.”