Mars Lake Hypothesis on Ice After Study Offers Different Explanation

Scientists have long debated what's under the surface of Mars' south pole. A new study points to clays being more likely than a subsurface lake.

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For years, scientists have been debating what might lay under the Martian planet’s south polar cap after bright radar reflections were discovered and initially attributed to water.

This image taken by UArizona’s HiRISE camera on NASA’s Mars Reconnaissance Orbiter shows ice sheets at Mars’ south pole. The spacecraft detected clays near this ice; scientists have proposed that such clays are the source of radar reflections previously interpreted as liquid water. NASA/JPL-Caltech/University of Arizona/JHU

Now, a new study involving a researcher from the University of Arizona puts that theory to rest and demonstrates that another material is most likely the answer.

The research, published in Geophysical Research Letters and led by York University planetary scientists in Canada, uses multiple lines of evidence to show that smectites, a common type of clay, can explain all of the observations – putting the Mars lake theory on ice.

“Since being first reported as bodies of water, the scientific community has shown skepticism about the lake hypothesis,” said principal investigator Isaac Smith, Canada Research Chair and assistant professor of earth and space science at York University. “And recent publications questioned if it was even possible to have liquid water.”

Papers in 2018 and 2021 demonstrated that the amount of salt and heat required to thaw ice at the bottom of the polar cap was many times more than Mars provides, and recent evidence showing these radar detections are much more widespread – to places even harder to thaw ice – put the idea further into question.

Stefano Nerozzi. By UArizona

The research team – which included Stefano Nerozzi, a postdoctoral fellow in the University of Arizona Lunar and Planetary Laboratory and Department of Geosciences, as well as researchers from Cornell, Purdue, and Tulane universities – used experimental and modeling work to demonstrate that smectites can better explain the radar observations made by the MARSIS instrument aboard the European Space Agency’s Mars Express orbiter. Further, they found spectral evidence that smectites are present at the edges of the south polar cap.

“Smectites are very abundant on Mars, covering about half the planet, especially in the Southern Hemisphere,” said Smith. “That knowledge, along with the radar properties of smectites at cryogenic temperatures, points to them being the most likely explanation to the riddle.”

“Based on observations, the first reason the bright reflectors cannot be water is because some of them continue from underground onto the surface. If that is the case, then we should see springs, which we don’t,” Nerozzi said. “Not only that, but multiple reflectors are stacked on top of each other, and some are even found right in the middle of the polar cap. If this were water, this would be physically impossible.”

Experiments also measured the radar characteristics of hydrated smectites at room temperature and cryogenic temperatures. The radar characteristics in question are two numbers that represent the real and imaginary parts of the permittivity, which tells you about the material’s electrical properties and response to the radio waves employed by radars. Both numbers are important for fully characterizing a material, but the 2018 study used modeling that included only the real part of the dielectric value, leaving out certain classes of materials from being considered – namely clays.

Once the experimental measurements were completed, data was evaluated using code. It was in these simulations that researchers found that, unlike the original liquid water hypothesis, frozen clays have numbers just right to explain all the reflections.

Smectites are a class of clay that is formed when basalt – the volcanic rock that comprises most of Mars’ surface – breaks down chemically in the presence of liquid water.

“Detecting possible clay minerals in and below the south polar ice cap is important because it tells us that the ice includes sediments that have interacted with water sometime in the past, either in the ice cap or before the ice was there,” said Briony Horgan, co-author and associate professor of earth, atmospheric and planetary sciences at Purdue University. “So, while our work shows that there may not be liquid water and an associated habitable environment for life under the cap today, it does tell us about water that existed in this area in the past.”

To support the new hypothesis, Smith conducted experiments in his lab with equipment designed for measuring dielectric values. To simulate the conditions beneath Mars’ south polar cap as best as possible, his team froze the clays to minus 50 degrees Celsius and measured them again, something that had never been done before. Smith adds that the infrared absorptions attributable to these minerals are present in south polar orbital visible-near infrared reflectance spectra. Because these minerals are both present at the south pole and can cause the reflections, the team believes this to be a more viable scenario than the presence of liquid water. No salt or heat is required.

“We used our lab measurements of clay minerals as the input for a radar reflection model and found that the results of the model matched very well with the real, observed data,” said Dan Lalich, postdoctoral researcher at the Cornell Center for Astrophysics and Planetary Science at Cornell University and second author on the study. “While it’s disappointing that liquid water might not actually be present below the ice today, this is still a cool observation that might help us learn more about conditions on ancient Mars.”

“We analyzed the MARSIS radar data and identified observations with high-power values at the base of the south polar layered deposits, both in the proposed lake region and elsewhere,” said Jenny Whitten, co-author and planetary scientist in the Department of Earth and Environmental Sciences at Tulane University.

Putting the results in perspective Smith says the answer is clear.

“Now, we have the trifecta. One, we measured dielectric properties of materials that are known to exist over 50% of Mars’ surface and found them to have very high values. Two, we modeled how those numbers would respond in Mars’ south-polar conditions and found them to match the radar observations well. Three, we demonstrated that these minerals are at the south pole. Because the liquid water theory required incredible amounts of heat, which is six to eight times more than Mars provides, and more salt than Mars has, it was already implausible. Now, the clays can explain the observations with absolutely no qualifiers or asterisks.”


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