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https://www.keele.ac.uk/pressreleases/2017/atmospheredetectedaroundanearth-likeplanet.html
Atmosphere detected around an Earth-like planet
Posted on 06 April 2017
Astronomers have detected an atmosphere around the super-Earth planet GJ 1132b. This marks the first detection of an atmosphere around an Earth-like planet other than Earth itself, and thus is a significant step on the path towards the detection of life outside our Solar System. The team that made the discovery, led by Keele University’s Dr John Southworth, used the 2.2 m ESO/MPG telescope in Chile to take images of the planet’s host star GJ 1132. They were able to measure the slight decrease in brightness as the planet and its atmosphere absorbed some of the starlight while transiting (passing in front of) the host star.
Dr John Southworth explains:
“While this is not the detection of life on another planet, it’s an important step in the right direction: the detection of an atmosphere around the super-Earth GJ 1132b marks the first time that an atmosphere has been detected around an Earth-like planet other than Earth itself.”
Is there life out there?
Astronomers’ current strategy for finding life on another planet is to detect the chemical composition of that planet’s atmosphere, on the look-out for chemical imbalances which could be caused by living organisms. In the case of our own Earth, the presence of large amounts of oxygen is a tell-tale sign of life.
Until these findings by Dr Southworth’s team, the only previous detections of exoplanet atmospheres all involved gas giants reminiscent of a high-temperature Jupiter.
Dr Southworth says that whilst we’re still a long way from detecting life on exoplanets, this discovery is the first step:
“With this research, we have taken the first tentative step into studying the atmospheres of smaller, Earth-like, planets. We simulated a range of possible atmospheres for this planet, finding that those rich in water and/or methane would explain the observations of GJ 1132b. The planet is significantly hotter and a bit larger than Earth, so one possibility is that it is a “water world” with an atmosphere of hot steam.”
Studying atmospheres
The planet in question, GJ 1132b, orbits the very low-mass star GJ 1132 in the Southern constellation Vela, at a distance of 39 light-years from Earth. The system was studied by a team led by John Southworth (Keele University, UK) and Luigi Mancini (currently at the University of Rome Tor Vergata), and including researchers from the Max Planck Institute for Astronomy (MPIA, Germany) and the University of Cambridge.
The team used the GROND imager at the 2.2 m ESO/MPG telescope of the European Southern Observatory in Chile to observe the planet simultaneously at seven different wavelength bands spanning the optical and near-infrared. As GJ 1132b is a transiting planet, it passes directly between Earth and its host star every 1.6 days, blocking a small fraction of the star’s light. From the amount of light lost, astronomers can deduce the planet’s size – in this case only 1.4 times that of Earth.
Crucially, the new observations showed the planet to be larger in one of the seven wavelength bands. This suggests the presence of an atmosphere that is opaque to this specific light (making the planet appear larger), but transparent to all the others.
The discovery of this atmosphere is encouraging. Very low-mass stars are extremely common (much more so that Sun-like stars), and are known to host lots of small planets. But they also show a lot of magnetic activity, causing high levels of X-rays and ultraviolet light to be produced which might completely evaporate the planets’ atmospheres. However, the properties of GJ 1132b show that an atmosphere can endure this for billion of years without being destroyed. Given the huge number of very low-mass stars and planets, this could mean that the conditions suitable for life are common in the Universe.
This discovery makes GJ 1132b one of the highest-priority targets for further study by the current top facilities, such as the Hubble Space Telescope and ESO’s Very Large Telescope, as well as the James Webb Space Telescope which is slated for launch in 2018.
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The team was led by John Southworth (Keele University) and also included Luigi Mancini (Max Planck Institute for Astronomy [MPIA], Universita die Roma Tor Vergata), Nikku Madhusudhan (University of Cambridge), Paul Mollière (MPIA), Simona Ciceri (Stockholm University), and Thomas Henning (MPIA).
The work described here has been published as J. Southworth et al., “Detection of the atmosphere of the 1.6 Earth mass exoplanet GJ 1132B” in the Astronomical Journal, volume 153, paper number 191, year 2017.
Agamemnonxhttp://yournewswire.com/super-earth-aliens/
Super-Earth Could Be Inhabited By Aliens, Say Scientists
April 7, 2017 Sean Adl-Tabatabai Sci/Environment 0
Astronomers say super-Earth could be inhabited by aliensAstronomers at the Max Planck Institute for Astronomy have hinted that super-Earth Gliese 1132b could be home to extraterrestrial life.
According to a recent announcement, astronomers have detected an atmosphere around the Earth-like planet, which is 39 light-years from our own.
While the finding doesn’t yet confirm the existence of life, scientists say it is a step in the right direction.
Phys.org reports:
The team, which includes researchers from the Max Planck Institute for Astronomy, used the 2.2-m ESO/MPG telescope in Chile to take images of the planet’s host star, GJ 1132, and measured the slight decrease in brightness as the planet and its atmosphere absorbed some of the starlight while passing directly in front of their host star.
While it’s not the detection of life on another planet, it’s an important step in the right direction: the detection of an atmosphere around the super-Earth GJ 1132b marks the first time an atmosphere has been detected around a planet with a mass and radius close to Earth’s mass and radius (1.6 Earth masses, 1.4 Earth radii).
Astronomers’ current strategy for finding life on another planet is to detect the chemical composition of that planet’s atmosphere, on the lookout for certain chemical imbalances that require the presence of living organisms as an explanation. In the case of our own Earth, the presence of large amounts of oxygen is such a trace.
We’re still a long way from that detection though. Until the work described in this article, the (few!) observations of light from exoplanet atmospheres all involved planets much more massive than Earth: gas giants—relatives of our own solar system’s Jupiter—and a large super-Earth with more than eight times the Earth’s mass. With the present observation, we’ve taken the first tentative steps into analyzing the atmosphere of smaller, lower-mass planets that are much more Earth-like in size and mass.
The planet in question, GJ 1132b, orbits the red dwarf star GJ 1132 in the southern constellation Vela, at a distance of 39 light-years from us. Recently, the system has come under scrutiny by a team led by John Southworth (Keele University, UK). The project was conceived, and the observations coordinated, by Luigi Mancini, formerly of the Max Planck Institute for Astronomy (MPIA) and now working at the University of Rome Tor Vergata. Additional MPIA team members were Paul Mollière and Thomas Henning.
The team used the GROND imager at the 2.2-m ESO/MPG telescope of the European Southern Observatory in Chile to observe the planet simultaneously in seven different wavelength bands. GJ 1132b is a transiting planet: From the perspective of an observer on Earth, it passes directly in front of its star every 1.6 days, blocking some of the star’s light.
The size of stars like GJ 1132 is well known from stellar models. From the fraction of starlight blocked by the planet, astronomers can deduce the planet’s size—in this case around 1.4 times the size of the Earth. Crucially, the new observations showed the planet to be larger at one of the infrared wavelengths than at the others. This suggests the presence of an atmosphere that is opaque to this specific infrared light (making the planet appear larger) but transparent at all the others. Different possible versions of the atmosphere were then simulated by team members at the University of Cambridge and the Max Planck Institute for Astronomy. According to those models, an atmosphere rich in water and methane would explain the observations very well.
The discovery comes with the usual exoplanet caveats: while somewhat larger than Earth, and with 1.6 times Earth’s mass (as determined by earlier measurements), observations to date do not provide sufficient data to decide how similar or dissimilar GJ 1132b is to Earth. Possibilities include a “water world” with an atmosphere of hot steam.
The presence of the atmosphere is a reason for cautious optimism. M dwarfs are the most common types of star, and show high levels of activity; for some set-ups, this activity (in the shape of flares and particle streams) can be expected to blow away nearby planets’ atmospheres. GJ 1132b provides a hopeful counterexample of an atmosphere that has endured for billion of years (that is, long enough for us to detect it). Given the great number of M dwarf stars, such atmospheres could mean that the preconditions for life are quite common in the universe.
In any case, the new observations make GJ 1132b a high-priority target for further study by instruments such as the Hubble Space Telescope, ESO’s Very Large Telescope, and the James Webb Space Telescope slated for launch in 2018.
AgamemnonNASA is sending a probe to Jupiter’s moon, Europa in the 2020’s. It will orbit Jupiter and take high resolution photos of Europa as it passes by to see if it has the conditions to support life as we know it. The probe will fly past it 45 times as it orbits Jupiter so there will be plenty of opportunities for good pictures. It is thought that Europa has a layer of frozen water on the surface and a liquid water ocean underneath the ice. The moon doesn’t freeze solid because tidal forces from Jupiter’s gravitational pull cause Europa to ‘flex’ which stimulates volcanic activity and generates enough heat to keep the interior liquified.
Besides Earth, Europa has the best chance to harbor life of any place in the solar system. If we don’t find it there we probably won’t find it anywhere. Although life almost certainly exists elsewhere in the universe, anything outside our solar system would be unattainable to us because of the distances involved (lucky for them).
oh yeah. i’m not necessarily thinking in terms of potential colonization. i just want evidence that it’s out there somewhere. in terms of probability, it’s a virtual certainty. but it’d just be cool to see. and does such a discovery affect society knowing we’re not alone? meaning the planet as a whole.
and not even necessarily intelligent life although i’m sure that exists somewhere if not here.
There is one theory (and it;’s pure theory) that they have already detected such traces of chemical imbalance on Saturn’s moon Titan.
If Titan has living organisms they would be very different from earth-based ones, since they would have to live in methane lakes and consume hydrogen. That’s one theory anyway.
i remember reading about titan and it’s methane lakes. i didn’t know they had found chemical imbalances though.
but yeah. it doesn’t even have to be life dependent on water. doesn’t even have to be carbon based.
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