In 2015, the New Horizons space probe discovered spectacular snowcapped mountains on Pluto, which are strikingly similar to mountains on Earth. Such a landscape had never before been observed elsewhere in the Solar System.
However, as atmospheric temperatures on our planet decrease at altitude, on Pluto they heat up at altitude as a result of solar radiation. So where does this ice come from?
An international team led by CNRS scientists* conducted this exploration. They first determined that the “snow” on Pluto’s mountains actually consists of frozen methane, with traces of this gas being present in Pluto’s atmosphere, just like water vapor on Earth.
Then, to understand how the same landscape could be produced in such different conditions, they used a climate model for the dwarf planet, which revealed that due to its particular dynamics, Pluto’s atmosphere is rich in gaseous methane at altitudes.
As a result, it is only at the peaks of mountains high enough to reach this enriched zone that the air contains enough methane for it to condense. At lower altitudes, the air is too low in methane for ice to form.
This research, published in the journal Nature Communications, could also explain why the thick glaciers consisting of methane observed elsewhere on Pluto bristle with spectacular craggy ridges, unlike Earth’s flat glaciers, which consist of water.
*Scientists from the IPSL Dynamic Meteorology Laboratory (CNRS / Sorbonne Université / École polytechnique / ENS Paris), the Institute for Planetary Sciences and Astrophysics of Grenoble (CNRS / Université Grenoble Alpes), the NASA Ames Research Center, and the Lowell Observatory (Unite States) took part in this research.
For more on this research:
- Pluto’s Ice Caps Made of Methane, Turns Earth’s Process Upside Down
- Earth vs. Pluto: Snowy and Icy Peaks with Very Different Origins
Reference: “Equatorial mountains on Pluto are covered by methane frosts resulting from a unique atmospheric process” by Tanguy Bertrand, François Forget, Bernard Schmitt, Oliver L. White and William M. Grundy, 13 October 2020, Nature Communications.