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  • Beneath the thin atmosphere of Mars lies an enigma: a desert landscape shaped by flowing water.

  • In the distant past, Mars must have had a warmer, wetter climate,

  • but scientists wonder: just how wet was ancient Mars?

  • [ Villanueva ] So in the ancient past, we have some indications that water was flowing on the surface, but how much water was there?

  • Are we talking about oceans, are we talking about small rivers, a little rain?

  • So these definitions of how much water was on the planet was very undefined.

  • [ Mumma ] A major question has been: how much water did Mars actually have when it was young, and how did it lose that water?

  • To answer this question, a team of researchers at NASA's Goddard Space Flight Center

  • used infrared telescopes on Earth to study water molecules in the Martian atmosphere.

  • [ Mumma ] We used the world's three major telescopes for infrared astronomy.

  • From the ground we could actually take a snapshot of the whole hemisphere of the planet on a single night.

  • The new infrared maps reveal the atmospheric ratio of normal to heavy water molecules at different locations and seasons on Mars.

  • Heavy water molecules contain a heavy isotope of hydrogen called deuterium,

  • which remains trapped in the Martian water cycle while normal hydrogen is lost to space.

  • The researchers found that water from the polar ice caps is highly enriched in deuterium,

  • indicating that Mars has lost a tremendous quantity of water.

  • Now we know that Mars water is much more enriched than terrestrial ocean water in the heavy form of water, the deuterated form.

  • Immediately that permits us to estimate the amount of water Mars has lost since it was young.

  • The findings indicate that only 13% of an ancient ocean remains on the planet today, now stored in the polar ice caps.

  • 87% of this ocean has been lost to space. This means that early Mars would have looked much different than it does today,

  • with a significant portion of its surface covered by water.

  • [ Mumma ] So the really interesting question is, could it form a sea or an ocean? And indeed, it would.

  • In the northern plains, which is a relatively flat region but depressed from the rest of the planet,

  • it would form an ocean that was approximately 20% of the planet's surface area.

  • And so that is a respectable ocean.

  • By combining Martian topography with the new estimate for water loss,

  • the researchers were able to simulate Mars' ancient ocean, and its escape to space.

  • As Mars lost its atmosphere over billions of years, it lost the pressure and heat needed to keep water liquid,

  • causing the ocean to shrink and recede northward.

  • The remaining water eventually condensed and froze over the north and south poles, giving Mars the ice caps that we see today.

  • This new scenario means that Mars would have stayed wet for longer than previously thought, expanding its ancient habitability.

  • We now know that Mars was wet for a much longer time than we thought before.

  • Curiosity shows it was wet for one-and-a-half-billion years, already much longer

  • than the period of time needed for life to develop on Earth,

  • and now we see that Mars must have been wet for a period even longer.

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