An artists impression of GJ 436b can be seen in the background in this image. Credit: NASA/JPL-Caltech
Astronomers have discovered a comet-like exoplanet that trails a huge, Rapunzel-like hair made of gas behind it. The research team focused the Hubble Space Telescope on an exoplanet that had already been seen losing its atmosphere, which forms an enormous cloud of hydrogen, giving the planet the appearance of a giant comet. During earlier observations in 2015, it was not possible to cover the whole cloud, whose shape was predicted by numerical simulations. Thanks to these new observations, however, the scientists have finally been able to confirm the initial predictions.
Exoplanet GJ 436b is similar in size to Neptune (i.e. about four times larger than Earth). Seen through UV glasses, it reveals a huge, Rapunzel-like hair made of gas. This phenomenon, detected in 2015 by astronomers from UNIGE’s Faculty of Sciences Observatory, could be due to the planet proximity to its host star: it takes the planet no more than three days to circle around it. The planet loses a part of its hydrogen-rich atmosphere because of the intense stellar irradiation. The lost atmosphere remains for some time around the planet in the form of a huge cloud of gas, which absorbs UV radiation from the star. This is why the cloud can only be seen with Hubble’s UV eye.
“We were flabbergasted by the mere size of the cloud, which our initial observations could not cover in its entirety as it passes in front of the star,” explains David Ehrenreich, associate professor at UNIGE and principal investigator of the European Research Council-funded project Four Aces, who obtained the observations. The team extrapolated the initial data with a numerical model, to predict what could be the cloud exact shape. The simulation resulted in a comet-like cloud with a trailing tail stretching over tens of millions of kilometres.
The team headed by Baptiste Lavie, a PlanetS PhD student at UNIGE, directed Hubble at GJ 436b afresh. The findings backed up the researchers’ predictions in every respect. The data injected into the numerical model explained the observations accurately: “We even took into account the pressure that the light from the star exerts on the hydrogen atoms that escape from the planet!” says Vincent Bourrier, the UNIGE astronomer who developed the digital model.
Solving the mystery of this rare phenomenon means the researchers are now in a position to understand how it affects other exoplanets, some receiving even more irradiation than GJ 436b. “We’re expecting some more surprises,” says Lavie with a smile.
https://eurekalert.org/pub_releases/2017-09/udg-tr091417.php
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