Analysis of Super-Earth atmosphere reveals potentially-habitable world

Analysis of Super-Earth atmosphere reveals potentially-habitable world
Artist’s impression of planet K2-18b: Is it a Super-Earth , or is it more of a mini-Neptune?
Artist’s impression of planet K2-18b: Is it a Super-Earth , or is it more of a mini-Neptune?
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Artist’s impression of planet K2-18b: Is it a Super-Earth , or is it more of a mini-Neptune?
Artist’s impression of planet K2-18b: Is it a Super-Earth , or is it more of a mini-Neptune?

Astronomers have analyzed the atmosphere of a nearby exoplanet and found that there are plenty of scenarios where it could have liquid water – and by extension, possibly life – on its surface. This new study adds weight to the idea that habitable exoplanets don’t have to be strictly Earth-sized.

The exoplanet in question is known as K2-18b. Located 124 light-years away, it orbits in its host star’s habitable zone, where temperatures are just right for water to potentially exist as a liquid on its surface. Better yet, last year astronomers detected large quantities of water vapor in its atmosphere.

K2-18b is about 2.6 times wider and 8.6 times more massive than our home planet, which places it between Earth and Neptune in size. Those two planets are obviously very different of course, so there’s quite a range of possibilities for what kind of world K2-18b may be.

Is it a Super-Earth – a large rocky world with a thin, hospitable atmosphere and water on the surface? Or is it more of a mini-Neptune, with a much thicker, suffocating atmosphere surrounding a smaller rocky core? The answer would drastically affect its habitability. So, astronomers on the new study set out to examine it in closer detail.

“Water vapor has been detected in the atmospheres of a number of exoplanets but, even if the planet is in the habitable zone, that doesn’t necessarily mean there are habitable conditions on the surface,” says Nikku Madhusudhan, lead researcher on the new study. “To establish the prospects for habitability, it is important to obtain a unified understanding of the interior and atmospheric conditions on the planet – in particular, whether liquid water can exist beneath the atmosphere.”

The main differences between an Earth-like and a Neptune-like exoplanet come down to the ratio of atmosphere-to-rock, as well as the composition of both. So astronomers from Cambridge analyzed the atmosphere of K2-18b, to determine what the most likely combinations were.

They confirmed that the atmosphere is rich in hydrogen, and contains plenty of water vapor. Interestingly, chemicals like methane and ammonia were lower than scientists might expect for this kind of atmosphere.

From this data, the team was able to examine the range of possible types of world that K2-18b is. They found that the hydrogen made up, at most, 6 percent of the planet’s mass, but could be as low as one-millionth of its total mass. That’s good news – the latter figure is comparable to Earth.

In fact, many of the scenarios that the study came up with painted K2-18b as a water world, with oceans at a pleasant and life-sustaining temperature and pressure on the surface.

“We wanted to know the thickness of the hydrogen envelope – how deep the hydrogen goes,” says Matthew Nixon, co-author of the study. “While this is a question with multiple solutions, we’ve shown that you don’t need much hydrogen to explain all the observations together.”

The team says that this analysis helps open up the search for potentially-habitable conditions to different types of exoplanets that might otherwise be ignored. Rocky Earth-sized planets are generally the favored candidates, but Super-Earths are actually the most common type of exoplanet. Knowing that they could host life is exciting, and gives astronomers far more places to look.

The research was published in The Astrophysical Journal Letters.

Source: Cambridge

Could? Possibly? Potentially? May? Possible? Could be? Might? Yup sounds like science to me.
High gravity planets are not suitable for humans. Think of the energy needed to get planes off the ground at just ONE g. Imagine what it would be like at multiples of that. Think what it takes to get a train up a hill; any railroads would need to be almost perfectly level. Same goes for trucks and cars. We would need to have fusion energy, with reactors small enough to be put on or in vehicles.