Science

Discovery: Nearby star hosts closest alien planet in the “habitable zone”

Image of sky area near Wolf 1061 (see details below)
Wednesday, 16 December, 2015
Deborah Smith

UNSW Australia astronomers have discovered the closest potentially habitable planet found outside our solar system so far, orbiting a star just 14 light years away.

The planet, more than four times the mass of the Earth, is one of three that the team detected around a red dwarf star called Wolf 1061.

“It is a particularly exciting find because all three planets are of low enough mass to be potentially rocky and have a solid surface, and the middle planet, Wolf 1061c, sits within the ‘Goldilocks’ zone where it might be possible for liquid water – and maybe even life — to exist,” says lead study author UNSW’s Dr Duncan Wright.

“It is fascinating to look out at the vastness of space and think a star so very close to us – a near neighbour – could host a habitable planet.

“While a few other planets have been found that orbit stars closer to us than Wolf 1061, those planets are not considered to be remotely habitable,” Dr Wright says.

The three newly detected planets orbit the small, relatively cool and stable star about every 5, 18 and 67 days.  Their masses are at least 1.4, 4.3 and 5.2 times that of Earth, respectively.

The larger outer planet falls just outside the outer boundary of the habitable zone and is also likely to be rocky, while the smaller inner planet is too close to the star to be habitable.

The discovery will be published in The Astrophysical Journal Letters.

The UNSW team made the discovery using observations of Wolf 1061 collected by the HARPS spectrograph on the European Southern Observatory’s 3.6 metre telescope in La Silla in Chile.

“Our team has developed a new technique that improves the analysis of the data from this precise, purpose-built, planet-hunting instrument, and we have studied more than a decade’s worth of observations of Wolf 1061,” says Professor Chris Tinney, head of the Exoplanetary Science at UNSW group.

“These three planets right next door to us join the small but growing ranks of potentially habitable rocky worlds orbiting nearby stars cooler than our Sun.”

Small rocky planets like our own are now known to be abundant in our galaxy, and multi-planet systems also appear to be common. However most of the rocky exoplanets discovered so far are hundreds or thousands of light years away.

An exception is Gliese 667Cc which lies 22 light years from Earth. It orbits a red dwarf star every 28 days and is at least 4.5 times as massive as Earth.

“The close proximity of the planets around Wolf 1061 means there is a good chance these planets may pass across the face of the star. If they do, then it may be possible to study the atmospheres of these planets in future to see whether they would be conducive to life,” says team member UNSW’s  Dr Rob Wittenmyer.

Link to the paper

Media contacts:

Dr Duncan Wright: Duncan.Wright@unsw.edu.au

Professor Chris Tinney (in Chile): c.tinney@unsw.edu.au, skype: cgtinney

Dr Rob Wittenmyer: rob@unsw.edu.au

UNSW Science media liason: Deborah Smith: +61 2 9385 7307, +61 478 492 060, deborah.smith@unsw.edu.au

Media have permission to use the images and video about Wolf 1061 on this page.  

Image of sky area near Wolf 1061

Caption: The sky area in the constellation of Ophiucus near the red dwarf star Wolf 1061 which includes the impressive, but unrelated, star cluster Messier 104. Wolf 1061 is 14 light years away.

Credit: The "Aladin sky atlas" developed at CDS, Strasbourg Observatory, France

Movie and Graphic of the Wolf 1061 system

Caption: A simulation of the orbital configuration of the Wolf 1061 system. Wolf 1061 is an inactive red dwarf star, smaller and cooler than our sun, 14 light years away.

The orbits for the planets b, c and d (ordered from the inner planet to the outer) have periods of 4.9 days, 17.9 days and 67.2 days. In the simulation we show the planet orbits as all lying in a single plane.

The planetary habitable zone around the star is marked in green - the colours grade from red (where a planet would be too hot), through green (where the surface of a planet could sustain liquid water), through to blue (where a planet would be too cold).

Credit: This simulation was made using the Universe Sandbox 2 software from universesandbox.com