
A Mars crater may have once contained water that sloshed back and forth as a tide came and went. If that is true, it follows that Mars must have had a moon that was massive enough to exert a gravitational pull on the planet鈥檚 seas sufficient enough to create tides. Neither of the two moons it currently possesses are big enough for the job.
at Louisiana State University and his colleagues have found that traces of tidal activity seem to be preserved in thin layers within sedimentary rocks in Gale crater.
They analysed the sediment layers to obtain the period of the tides and the properties of the moon that helped cause them. If it indeed existed, it was 15 to 18 times as massive as Phobos, the largest of the Red Planet鈥檚 two present moons. This would still make it hundreds of thousands of times less massive than Earth鈥檚 moon. Today鈥檚 two Martian moons may in fact be remnants of the larger moon.
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Karunatillake will present the team鈥檚 results at next week鈥檚 annual meeting of the in New Orleans, Louisiana.
The rocks the researchers base their conclusions on were imaged by NASA鈥檚 Curiosity rover. They contain alternating layers of different thickness and colour. Such layers are called rhythmites, because they are a sign that material was brought in by a wind or current with a regularly varying strength. In the case of tides, the incoming tide brings sand, which is then covered with fine mud when the tide turns and the water is at a standstill.
The Gale rhythmites contain thin, dark lines suggesting such 鈥渕ud drapes鈥, which 鈥渟how a very close similarity with Earth tidal patterns鈥, says team member Priyabrata Das, also at Louisiana State University.
To strengthen the team鈥檚 hypothesis, at the Max Planck Institute for Solar System Research in Germany used a standard mathematical technique called a Fourier transform to analyse the pattern of layering in the Martian rocks. This identified additional periodicities in the layer thicknesses, suggesting that both the sun and a moon were once driving the tide, just like on Earth.
With that analysis, the researchers may have confirmed an idea first raised by at the German University of Technology in Oman. An expert on rhythmites, he suggested in 2023 that layered formations observed by NASA鈥檚 Perseverance rover in another Martian crater, Jezero, might be tidal. But those images didn鈥檛 have enough resolution to do a Fourier transform. Excited by the analysis of the Gale rhythmites, Mazumder points out that, on Earth, finding such rhythmites 鈥渋s a very robust proof of tidal activity. In other words: marine conditions.鈥
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But not everyone is convinced. The lakes inside Jezero and Gale craters, with their diameters of 45 and 154 kilometres, respectively, were too small to have tides, says at the Laboratory of Planetology and Geosciences in Nantes, France, who is a member of NASA鈥檚 Perseverance Mars team. 鈥淭hus, even with a larger moon in the past, I don鈥檛 think these two locations are the good ones to record tidal deposits.鈥
at the University of Tennessee, who works with NASA on Curiosity鈥檚 explorations, also sees problems with the larger moon idea, and notes that tidal-like rhythmites can be formed by regularly varying river inflows into a lake.
But Sarkar thinks there may be a way out for the tidal interpretation. 鈥淢aybe an ocean was hydrologically connected with Gale. Even subsurface porosity can connect bodies and cause tides. On Mars you have a highly fractured and cratered surface, so porosity is not a problem over there.鈥