New super-Earth detected within the habitable zone of a nearby cool star
This discovery demonstrates that habitable planets could form in a greater variety of environments than previously believed.
An international team of scientists led by Guillem Anglada-Escudé and Paul Butler from Carnegie in Washington, D.C., has discovered a potentially habitable super-Earth orbiting a nearby star. The star is a member of a triple-star system and has a different makeup than our Sun. This discovery demonstrates that habitable planets could form in a greater variety of environments than previously believed.
The team used public data from the European Southern Observatory (ESO) and analyzed it with a novel data analysis method. They also incorporated new measurements from the Keck Observatory’s High Resolution Echelle Spectrograph and the new Carnegie Planet Finder Spectrograph at the Magellan II Telescope.
Their planet-finding technique involved measuring the small wobbles in a star’s orbit in response to a planet’s gravity. Anglada-Escudé and his team focused on an M-class dwarf star called GJ 667C, which is 22 light-years away. It is a member of a triple-star system. The other two stars (GJ 667AB) are a pair of orange K dwarfs with a concentration of heavy elements only 25 percent that of our Sun’s. Such elements are the building blocks of terrestrial planets, so it was thought to be unusual for metal-depleted star systems to have an abundance of low-mass planets.
GJ 667C had previously been observed to have a super-Earth (GJ 667Cb) with a period of 7.2 days, although this finding was never published. This orbit is too tight, and thus hot, to support life. The new study started with the aim of obtaining the orbital parameters of this super-Earth.
But, in addition to this first candidate, the research team found the clear signal of a new planet (GJ 667Cc) with an orbital period of 28.15 days and a minimum mass of 4.5 times that of Earth. The new planet receives 90 percent of the light that Earth receives. However, because most of its incoming light is in the infrared, the planet should absorb a higher percentage of this incoming energy. When both of these effects are taken into account, the planet is expected to absorb about the same amount of energy from its star that Earth absorbs from the Sun. This would allow surface temperatures similar to Earth and perhaps liquid water, but this extreme cannot be confirmed without further information on the planet’s atmosphere.
“This planet is the new best candidate to support liquid water and, perhaps, life as we know it,” Anglada-Escudé said.
The team notes that the system might also contain a gas-giant planet and an additional super-Earth with an orbital period of 75 days; further observations are needed to confirm these two possibilities.
“With the advent of a new generation of instruments, researchers will be able to survey many M dwarf stars for similar planets and eventually look for spectroscopic signatures of life in one of these worlds,” he said.