High-precision spectrograph confirms massive exoplanet orbiting a low-mass star


High-precision NEID spectrograph helps confirm first Gaia astrometric planet discovery
Gaia-4b is a planet orbiting the star called Gaia-4, around 244 light-years away. Gaia-4b is about twelve times more massive than Jupiter. With an orbital period of 570 days, it is a relatively cold gas giant planet. Gaia-5b is a brown dwarf orbiting the star Gaia-5, around 134 light-years away from Earth. With a mass of around 21 Jupiters, Gaia-5b is more massive than a planet but too light to sustain the nuclear fusion necessary to be a star. This artist impression visualizes a portion of both objects’ orbital motions as determined by Gaia’s astrometric data. The stars and planets are not to scale. Credit: ESA/Gaia/DPAC/M. Marcussen

With an assist from the NEID spectrograph, a team of astronomers have confirmed the existence of exoplanet Gaia-4b—one of the most massive planets known to orbit a low-mass star. Gaia-4b is also the first planet detected by the European Space Agency’s Gaia spacecraft using the astrometric technique.

NEID is a high-precision radial-velocity spectrograph that is designed to measure the extremely minute wobble of using the radial velocity effect. This effect results from the mutual gravitational force between a planet and its which causes the star’s position to shift very slightly as the planet travels around it. With this powerful capability, one of NEID’s main science goals is to confirm exoplanet candidates found by other exoplanet missions.

NEID is mounted on the WIYN 3.5-meter Telescope at the U.S. National Science Foundation Kitt Peak National Observatory (KPNO), a program of NSF NOIRLab.

One mission that NEID is complementing is the European Space Agency’s (ESA) Gaia spacecraft. Through its precise monitoring of the positions and motions of stars in our galaxy, Gaia is revolutionizing our understanding of many areas of astrophysics. With its exquisite precision, Gaia is expected to be able to detect thousands of exoplanets in orbit around nearby stars.

Unlike the used by NEID, Gaia uses a technique known as astrometry to detect a star’s motion. This technique involves measuring the subtle motion of a star as it is tugged by the gravity of an orbiting planet by looking at how the star moves compared to background or nearby stars.

Recently, as part of the latest Gaia data release, a list of stars that appear to be moving as though pulled by an exoplanet—the list of Gaia AStrometric Objects of Interest (Gaia-ASOIs)—was published.

“However, the motion of these stars is not necessarily due to a planet,” said Guðmundur Stefánsson, assistant professor at the University of Amsterdam and lead author of the paper appearing in The Astrophysical Journal.

“Instead, the ‘star’ might be a pair of stars that are too close together for Gaia to recognize them as separate objects. The tiny shifts in position that appear to be due to a planet might actually result from the nearly perfect cancellation of the larger shifts in position of the two stars.”







Using in part the NEID spectrograph mounted on the WIYN 3.5-meter Telescope at the U.S. National Science Foundation Kitt Peak National Observatory, a Program of NSF NOIRLab, a team of astronomers have confirmed the existence of exoplanet Gaia-4b—one of the most massive planets known to orbit a low-mass star. Gaia-4b is also the first planet detected by the European Space Agency’s Gaia spacecraft using the astrometric technique. This animation visualises a portion of Gaia-4b’s orbital motions as determined by Gaia’s astrometric data. The star and planet are not to scale. Credit: ESA/Gaia/DPAC/M. Marcussen

To weed out these and harvest the true planets, it is necessary to conduct follow-up observations with spectroscopy. To do so, the team used observations from NEID and two other spectrographs: the Habitable-zone Planet Finder (HPF) on the 10-meter Hobby Eberly Telescope at McDonald Observatory in Texas, and the FIES Spectrograph on the 2.6-meter Nordic Optical Telescope at La Palma in the Canary Islands.

With these powerful instruments, the team conducted follow-up observations of 28 with planet candidates identified by Gaia. They found that of the 28 candidate systems, 21 were and were actually binary star systems—two stars that orbit a common center of mass. They also confirmed that one system is a star hosting a brown dwarf—an object with a mass in between those of planets and stars—but one was a star hosting a giant planet.

The newly discovered exoplanet, named Gaia-4b, has an of 570 days and a mass of 12 Jupiter masses and orbits a star 64% of the mass of the sun. Not only is Gaia-4b the first planet ever detected by Gaia using the astrometric technique whose orbital solution is fully and independently confirmed, but it is also one of the most massive planets known to orbit a low-mass star.







Using data from the European Space Agency’s Gaia mission, scientists have found a brown dwarf, named Gaia-5b, orbiting a low-mass star. Gaia-5b orbits the star Gaia-5, around 134 light-years away from Earth, and has a mass of around 21 Jupiters. This animation visualizes a portion of Gaia-5b’s orbital motion as determined by Gaia’s astrometric data. The star and planet are not to scale. Credit: ESA/Gaia/DPAC/M. Marcussen

“It is an exciting time for both NEID and Gaia,” says Jayadev Rajagopal, scientist at NSF NOIRLab and a co-author of the paper. “Gaia is more than living up to its promise of detecting planetary companions to stars with highly precise astrometry, and NEID is demonstrating that its long-term radial velocity precision is capable of detecting low-mass planets around those stars.

“With more candidate planets to come as roughly the last year of data is analyzed, this work is a harbinger of the future where Gaia discoveries of planets and brown dwarfs will need to be confirmed, or rejected, by NEID data.”

In addition to the detection of Gaia-4b and Gaia-5b, the authors provide a first glimpse of the “false positive rate” of the Gaia Astrometric Exoplanet catalog, which is in the range 30–80% in their sample. This highlights the importance of ground-based observations like those possible with NEID in confirming planetary candidates in the Gaia-planet-detection era.

More information:
Gudmundur Stefánsson et al, Gaia-4b and 5b: Radial Velocity Confirmation of Gaia Astrometric Orbital Solutions Reveal a Massive Planet and a Brown Dwarf Orbiting Low-mass Stars, The Astronomical Journal (2025). DOI: 10.3847/1538-3881/ada9e1

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High-precision spectrograph confirms massive exoplanet orbiting a low-mass star (2025, February 4)
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