![\"Professor](\"https:\/\/www.open.ac.uk\/blogs\/news\/wp-content\/uploads\/2018\/11\/Carole_haswell-300x203.jpg\")
Professor Carole Haswell<\/p><\/div>\n
The discovery features in a paper due to be published on Thursday 15th<\/sup> November in Nature<\/em><\/a>, co-authored by three OU astronomers: Professor Carole Haswell, Post-Doctoral Researcher Dr John Barnes and former OU PhD student Dr Daniel Staab.<\/p>\n Measurements from high-precision instruments reveal the cold super-Earth around Barnard\u2019s star. This red dwarf star is famous because it moves across the night sky faster than any other. Only the three stars of the Alpha Centauri triple star system are closer to our own Solar System than Barnard\u2019s Star.<\/p>\n The astronomers obtained significant evidence of a planet with mass just over three times the Earth\u2019s mass orbiting the red dwarf star every 233 days. Because red dwarf stars are dimmer than the Sun, the super-Earth is orbiting near the so-called snow-line of the star, where it is likely to be a frozen world.<\/p>\n The planet candidate, named Barnard\u2019s star b<\/strong> (or GJ 699 b), is a super-Earth with at least 3.2 Earth masses. In the absence of an atmosphere, its temperature is likely to be about -150\u00b0 C, which makes it unlikely that the planet can sustain liquid water on its surface. Current theories of planetary formation predict that the snow-line \u2014 the location of the planet Barnard\u2019s star b\u00a0<\/strong>\u2014 is the ideal location for such planets to form.<\/p>\n Graphic represents relative distances to nearest stars from the Sun. Photo credit: IEEC\/Science-Wave – Guillem Ramisa<\/p><\/div>\n This is the first time astronomers have discovered a cool, probably rocky exoplanet using the so-called radial velocity method. The team used two decades of observations, including recent measurements from the state-of-the-art planet hunting instrument CARMENES, which is based in Calar Alto, Spain.<\/p>\n Barnard\u2019s star is a red dwarf<\/a><\/u>: a cool, low-mass star. The most common type of planet to form around low-mass stars are super-Earths<\/a><\/u>, lending credibility to this newly discovered planetary candidate.<\/p>\n Because it is only six light-years from us, as it orbits around our Milky Way Galaxy, Barnard\u2019s star appears to move across Earth\u2019s night sky faster than any other star. This red-dwarf star, smaller and older than our Sun, is among the least active red dwarfs known and is consequently an ideal target to search for exoplanets with various methods.<\/p>\n Because stellar activity generates energetic X-rays and UV radiation, active stars may prevent life evolving on any orbiting planets. In contrast, old inactive stars like Barnard\u2019s star are more favourable for life. However the researchers find no sign of any planets within the so-called \u2018habitable zone\u2019 where temperatures are consistent with liquid water on the planet\u2019s surface.<\/p>\n Since 1997, several instruments have been gathering copious measurements of Barnard\u2019s star\u2019s subtle back-and-forth wobble. An analysis of the data collected up to 2015, including observations from HIRES\/Keck, and ESO\u2019s HARPS and UVES spectrometers, suggested the wobble could be caused by a planet with an orbital period of about 230 days. To confirm this, however, more measurements were deemed necessary.<\/p>\n To confirm the planet, the Red Dots team of astronomers regularly monitored Barnard\u2019s star with high precision spectrometers such as CARMENES (Calar Alto Observatory in Spain), and also HARPS and HARPS-N in an international effort \u00a0[2]. The radial velocity technique uses the Doppler effect on the light from Barnard\u2019s star [1] to measure how the star moves as a consequence of the gravity of the orbiting planet<\/p>\n Dr Ignasi Ribas, lead astronomer, from the Institute of Space Studies of Catalonia said:<\/p>\n For the analysis we used observations from seven different instruments, spanning 20 years, making this one of the largest and most extensive datasets ever used for precise radial velocity studies. The combination of all data led to a total of 771 measurements.<\/p><\/blockquote>\n Dr Ribas explained that a clear signal at a period of 233 days arose again in the re-analysis of all the measurements combined. He said: \u201cThis signal implies that Barnard\u2019s star is approaching and moving away from us at about 1.2 m\/s \u2014 approximately the walking speed of a person \u2014 and it is best explained by a planet orbiting it.”<\/p>\n Artist’s impression Barnard’s Star b. Credit: IEEC\/Science-Wave – Guillem Ramisa<\/p><\/div>\n \u201cAfter a very careful analysis, we are over 99% confident that the planet is there, since this is the model that best fits our observations,\u201d said Ribas.<\/p>\n \u201cHowever, we must remain cautious and collect more data to nail the case in the future, because natural variations of the stellar brightness resulting from starspots can produce similar effects to the ones detected.\u201d<\/p>\n Follow-up observations are already underway at various observatories.<\/p>\n \u201cWe all have worked very hard on this result,\u201d said Guillem Anglada-Escude from Queen Mary University of London and co-leader of this work. \u201cThis is the result of a large collaboration organised in the context of the Red Dots project, which is why it has contributions from teams all over the world including semi-professional astronomers coordinated by the AAVSO.\u201d<\/p>\n Whilst unlikely to be habitable, because it\u2019s too cold, Barnard\u2019s star b<\/strong> is an excellent target for direct imaging using the next generation of instruments such as NASA\u2019s Wide Field InfraRed Survey Telescope (WFIRST, [3]).<\/p>\n Such low mass exoplanets so distant from their parent star have not been discovered before by the Doppler technique [1]. This means that astronomers are getting better at finding and exploring a relatively new kind of planet outside our Solar System. With the next generation of instruments, these capabilities can only expand.<\/p>\n Prof Carole Haswell, Head of Astronomy at the Open University and co-author of the paper said:<\/p>\n While the starlight from Barnard\u2019s star is too feeble for Barnard\u2019s star b to have liquid water on its surface, Barnard\u2019s star b <\/strong>probably has a similar temperature to Jupiter\u2019s moon Europa. Famously, Europa has a sub-surface ocean which has been considered as a potential habitat for life. It is possible Barnard\u2019s star b may offer similar niches for life.”<\/p><\/blockquote>\n \u201cThe planet is over three times more massive than the Earth, so any future explorers will find its stronger gravity make it a physically tiring world to visit.\u201d added Dr John Barnes, Researcher at The Open University, also a co-author of the paper.<\/p>\n \u201cTantalisingly, super-Earths like Barnard\u2019s star b<\/strong> probably sustain geothermal activity for longer than their lower mass counterparts. This could be helpful to life by providing sustained heat and the chemicals needed to build complex organic molecules.\u201d said Professor Haswell.<\/p>\n \u201cThis new discovery offers exciting prospects to learn more about the Galaxy\u2019s diversity of planetary systems, starting with our own Solar System\u2019s near neighbours.\u201d<\/p>\n Main image caption:<\/strong><\/p>\n Artistic impression of a Sunset from Barnard\u2019s star<\/p>\n Credits : Martin Kornmesser\/ESO.<\/p>\n License : CC BY 4.0<\/a><\/u><\/p>\n Notes <\/strong><\/p>\n [1] In the radial velocity method, precision spectrometers are used to measure the Doppler effect. When an object moves away from us, the light we observe becomes slightly less energetic and redder. The opposite -light becomes slightly more energetic and bluer- happens when the star comes to us.<\/p>\nCold and rocky<\/h2>\n
![\"Graphic](\"https:\/\/www.open.ac.uk\/blogs\/news\/wp-content\/uploads\/2018\/11\/Barnard-b-stars-300x170.png\")
Star’s wobble was investigated<\/h2>\n
![\"Barnard's](\"https:\/\/www.open.ac.uk\/blogs\/news\/wp-content\/uploads\/2018\/11\/Image1_BarnardB_DevTest-300x300.png\")
Unlikely to be habitable<\/h2>\n