Skip to main content

'Dead' telescope discovers Jupiter's twin from beyond the grave

The exoplanet, discovered by NASA's Kepler space telescope, officially designated K2-2016-BLG-0005Lb. (Image credit: D. Specht et al, Kepler K2 )

NASA's Kepler space telescope has spotted a Jupiter look-alike in a new discovery, even though the instrument stopped operations four years ago. 

An international team of astrophysicists using NASA's Kepler space telescope, which ceased operations in 2018, have discovered an exoplanet similar to Jupiter located 17,000 light-years from Earth, making it the farthest exoplanet ever found by Kepler. The exoplanet, officially designated K2-2016-BLG-0005Lb, was spotted in data captured by Kepler in 2016. Throughout its lifetime, Kepler observed over 2,700 now-confirmed planets. 

"Kepler was also able to observe uninterrupted by weather or daylight, allowing us to determine precisely the mass of the exoplanet and its orbital distance from its host star (opens in new tab)," Eamonn Kerins, an astronomer at the University of Manchester in the U.K., said in a statement (opens in new tab). "It is basically Jupiter's identical twin in terms of its mass and its position from its sun, which is about 60% of the mass of our own sun," 

Related: Never-before-seen rocks found in these exoplanet graveyards

The team, led by David Specht, a Ph.D. student at the University of Manchester, took advantage of a phenomenon known as gravitational microlensing (opens in new tab) to spot the exoplanet. With this phenomenon, which was predicted by Einstein's theory of relativity (opens in new tab), objects in space can be seen and studied closer when the light from a background star is warped and thus magnified by the gravity of a closer massive object. 

In hopes of using the warped light from a far-off star to detect an exoplanet, the team used three months of observations that Kepler made of the stretch of sky where this planet lies. 

"To see the effect at all requires almost perfect alignment between the foreground planetary system and a background star," Kerins added in the same statement. "The chance that a background star is affected this way by a planet is tens to hundreds of millions to one against. But there are hundreds of millions of stars towards the center of our galaxy. So Kepler just sat and watched them for three months."

The team then worked with Iain McDonald, another astronomer at the University of Manchester who developed a new search algorithm. Together, they were able to reveal five candidates in the data, with one most clearly showing signs of an exoplanet. Other ground-based observations of the same stretch of sky corroborated the same signals that Kepler saw of the possible exoplanet. 

"The difference in vantage point between Kepler and observers here on Earth allowed us to triangulate where along our sight line the planetary system is located," Kerins said.

Aside from the excitement of discovering an exoplanet with an instrument no longer even in service, the team's work is notable because Kepler was not designed to discover exoplanets using this phenomenon. It is important to note, however, that, in 2016, Kepler's mission was extended. In 2013, after two reaction wheel failures, it was proposed that Kepler be used for a K2 "second light" mission that would see the scope detecting potentially habitable exoplanets. This extension was approved in 2014 and the mission was extended way past the scope's expected end date until it eventually ran out of fuel on Oct. 30, 2018. 

"Kepler was never designed to find planets using microlensing so, in many ways, it's amazing that it has done so," Kerins said, adding that upcoming instruments like NASA's Nancy Grace Roman Space Telescope and the European Space Agency's Euclid mission, could be capable of using microlensing to study exoplanets and will be able to further such research. 

"Roman and Euclid, on the other hand, will be optimized for this kind of work. They will be able to complete the planet census started by Kepler," Kerins said. "We'll learn how typical the architecture of our own solar system is. The data will also allow us to test our ideas of how planets form. This is the start of a new exciting chapter in our search for other worlds."

This discovery was described in a study (opens in new tab) posted March 31 to the preprint server ArXiv.org and has been submitted for publication in the journal the Monthly Notices of the Royal Astronomical Society. 

Email Chelsea Gohd at cgohd@space.com or follow her on Twitter @chelsea_gohd (opens in new tab). Follow us on Twitter @Spacedotcom (opens in new tab) and on Facebook.

Chelsea Gohd joined Space.com as an intern in the summer of 2018 and returned as a Staff Writer in 2019. After receiving a B.S. in Public Health, she worked as a science communicator at the American Museum of Natural History. Chelsea has written for publications including Scientific American, Discover Magazine Blog, Astronomy Magazine, Live Science, All That is Interesting, AMNH Microbe Mondays blog, The Daily Targum and Roaring Earth. When not writing, reading or following the latest space and science discoveries, Chelsea is writing music, singing, playing guitar and performing with her band Foxanne (@foxannemusic). You can follow her on Twitter @chelsea_gohd.