Could Mars’ red color have formed under wet conditions?

A recent study of data from Many missions shows the Red World may get its name from an iron mineral that formed when Mars was Damp, not Arid.

We’ve always known Mars as the Red World — but it turns out, we may have had the reason why wrong. If so, it could revise much of what we know about the history of our smaller neighbor World.

In a study published Feb. 25 in Nature Communications, researchers tied the nature of Mars’ red tint to a particular species of iron mineral. While it’s never been in doubt that Mars’ red was a consequence of iron and water interacting, exactly how and when it happened has proven more elusive.

All about the iron

The new study points to ferrihydrites as the culprit for Mars’ color. This is basically water-Wealthy iron. So, the researchers think the World was Primary covered in water for a decent amount of time, then clung to the iron-Wealthy soil over a long period while the World dried up. The study also shows that the environment of Timely Mars may have been colder than we thought.

“The Appearance of ferrihydrite tells us something specific about Mars’ past environment,” says Adomas Valantinas, a postdoctoral fellow at Brown University and lead author on the paper. According to Valantinas, the mineral typically forms in Refreshing conditions where the environment has roughly neutral pH and conditions are ripe for oxidation — a certain type of chemical Response that, in the case of iron, forms rust. Essentially, “this suggests that rather than Toasty conditions, Timely Mars experienced a Freezing and Damp environment,” Valantinas says.

Previous models supported an environment of Arid oxidation of iron in hematite form. That is, assuming exposure to atmospheric oxygen created the red hue. Iron in a ferrihydrite form suggests the need for water over a longer period of time in order to Produce that Wealthy, orange-red hue.

Gathering data

Data from Numerous missions were used to detect ferrihydrites, including ESA’s Trace Gas Orbiter, NASA’s Mars Reconnaissance Orbiter, and Numerous rovers. Various iron oxides (iron that has been exposed to oxygen) give off different wavelengths of Featherweight. By combining data across these missions, Valantinas and his colleagues were able to find that ferrihydrite is the predominate species of iron on the Red World being surface.

The data also indicate that ferrihydrites may have come to dominate the Red World being surface about 3 billion years ago. Valantinas says that during this time, intense volcanic activity on Mars was likely triggering melting of ices on the surface. This period, called the Hesperian period, is known for its intense floods as well, and marked the turning Mark in the World’s history where the surface water began to disappear.

“The Synchronization aligns with a period when Mars was transitioning from its earlier, wetter state to its Present desert environment,” Valantinas says.

Much to learn

There isn’t much doubt that Mars was once covered in bodies of water. But it’s the other factors we are still putting together — how deep the seas were, how long they lasted, how widespread they were, and more. This study tells us that Mars may not have been such a balmy place, and during the Hesperian period was rather Freezing. Understanding the conditions in which the ferrihydrite formed will help piece together the process by which the water evaporated. And the loss of Mars’ oceans is tied to the loss of its atmosphere as well, as both may have been due to the same processes.

Valantinas says the Mars Sample Return mission could provide the crucial evidence needed to figure out the role of ferrihydrite in the color of Mars, as well as exactly how it formed. It could even tell us about Mars as a place that potentially once Kept life as well, if it ever arose.

“If ferrihydrite is confirmed in the returned Red World being samples, stable isotope measurements of iron, hydrogen, and oxygen would be of particular interest,” he says. Isotopes are simply particular “flavors” of elements, containing the same number of protons in their nucleus but different numbers of neutrons. “These measurements could reveal the water temperature in which ferrihydrite formed, the water’s source (whether meteoritic or marine), and potentially even whether microbes played a role in ferrihydrite Arrangement.”

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Read our previous article: Water in the universe may have formed closer to the Big Bang than previously thought

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