Martian south polar cap composition focus of new study

Mars Express, a spacecraft launched by the European Space Agency in 2003, is the second longest surviving continually active spacecraft in orbit around a planet other than Earth, behind only NASA’s still active 2001 Mars Odyssey. As this spacecraft orbits Mars, it continues to provide important data on the Red Planet’s interior, subsurface, surface and atmosphere, and environment.

Onboard this spacecraft is an instrument called the Mars Advanced Radar for Subsurface and Ionosphere Sounding, or MARSIS for short. This instrument uses a radar sounder to assess the composition of the subsurface of Mars. 

Scientists studying Mars, using the MARSIS instrument data, have previously reported a regionally strong radar reflection under Mars’ south polar ice sheet and have interpreted these bright radar reflections at the base of the south polar ice cap as being caused by liquid water.

But a team of scientists, led by Carver Bierson of ASU’s School of Earth and Space Exploration, and using data from this same instrument, have determined that Mars’ south polar ice sheet may be made of clays, metal-bearing minerals, or saline ice. Their findings have been recently published in AGU’s Geophysical Research Letters.

“Our team wanted to step back and ask if there were other materials besides liquid water that could cause these bright reflections,” says lead author and planetary scientist Bierson. 

A radar reflection can be bright due to a large contrast in either dielectric permittivity (how a material responds to an electric field) or electric conductivity (the amount of electrical current a material can carry). While previous studies only considered contrasts in dielectric permittivity, Bierson and his team found that contrasts in electric conductivity between materials could also explain the brightness of the reflection.

Using Earth as an example, under the large ice sheets of Greenland and Antarctica, many materials have high electric conductivity, including very salty water (brines), salty ice deposits, and clays. 

“We wanted to check if this same wide range of materials might be able to explain the bright radar reflection under Mars’ south polar cap,” says Bierson.

Bierson’s team and co-authors include Earth glaciology expert Slawek Tulaczyk of the University of California Santa Cruz; graduate student Sam Courville of ASU, who conducted orbital radar modeling; and Mars radar measurements expert Nathaniel Putzig of the Planetary Science Institute.

Together, they were able to determine what level of electric conductivity the material below the ice would need to have to match the observed signal from MARSIS. Then, they identified materials that are both conductive and present on Mars including clays, metal-bearing minerals, and saline ice.

“Salty ice or conductive minerals at the base of the ice sheet are less flashy, but are more in line with the extremely cold temperatures at Mars poles,” says Bierson

While not explicitly excluding a liquid brine, the results open new potential explanations for the observed strong radar reflections, some of which do not require liquid brine beneath the Martian south polar ice cap. 

“Our results are a reminder that there is often more than one way to explain an observation,” says Bierson.

###

About Arizona State University

Arizona State University has developed a new model for the American Research University, creating an institution that is committed to access, excellence and impact. ASU measures itself by those it includes, not by those it excludes. As the prototype for a New American University, ASU pursues research that contributes to the public good, and ASU assumes major responsibility for the economic, social and cultural vitality of the communities that surround it.