LP 791-18 d, illustrated here, is an Earth-size world about 86 light-years away. The gravitational tug from a more massive planet in the system, shown as a blue dot in the background, may result in internal heating and volcanic eruptions on this exoplanet – as much as Jupiter’s moon Io, the most geologically active body in the Solar System. Credit: NASA’s Goddard Space Flight Center/Chris Smith (KRBwyle)
Astronomers from the Université de Montréal and members of the Centre for Research in Astrophysics of Québec (CRAQ) have discovered an Earth-sized exoplanet around a nearby small red dwarf star that is likely carpeted with volcanoes. The discovery offers an unprecedented opportunity to learn more about rocky worlds outside the Solar System
A large international team led by astronomers at the Trottier Institute for Research on Exoplanets at the Université de Montréal (UdeM), who are also members of the CRAQ, announces today the discovery of a new temperate world around a nearby small star in the journal Nature. This planet, named LP 791-18 d, has a radius and a mass consistent with those of Earth. Observations of this exoplanet and another one in the same system indicate that LP 791-18 d is likely covered with volcanoes similar to Jupiter’s moon Io, the most volcanically active body in our Solar System.
“The discovery of this exoplanet is an extraordinary find,“ said Professor Björn Benneke from UdeM’s Department of Physics. “The similarity in the properties of LP 791-18 d and Earth as well as the prospect of detectable geological activity and volcanism on it make it a key object to better understand how terrestrial worlds form and evolve.”
Thanks to the very small size of the star – which is only slightly bigger than planet Jupiter – it should be possible to detect the atmosphere of this exoplanet, if it has one, using the James Webb Space Telescope.
A new terrestrial world in a multi-planetary system
The planet discovery was led by Merrin Peterson, a graduate student in Benneke’s team at the UdeM-based Trottier Institute for Research on Exoplanets. It was found and studied using data from NASA’s Spitzer Space Telescope and Transiting Exoplanet Survey Satellite (TESS), as well as a suite of ground-based observatories all over the world.
LP 791-18 d orbits a small red dwarf star about 86 light-years away in the southern constellation Crater. The Spitzer Telescope saw the star’s infrared light dim slightly when the planet passed in front of its disc a phenomenon called a transit. The observations of the system in October 2019 were among the last Spitzer collected before it was decommissioned. Benneke’s team used the data to determine that the planet is virtually the same size as Earth. With an orbital period of only 2.8 days, the exoplanet LP 791-18 d is located very close to its host star. However, the star is much smaller and less bright than our Sun. The temperature on LP-791-18 d is thus only slightly higher than on Earth.
Astronomers have known about two other worlds in this system, planets LP 791-18 b and c, since 2019, when they were detected by the TESS satellite. Planet b is about 20% bigger than Earth and circles its star in a little less than a day, while Planet c is about 2.5 times Earth’s size and has a period of about 5 days. The newly found exoplanet d is thus the smallest in the family and orbits between planets b and c at an intermediate distance from the star.
By precisely tracking the movement of the planet, the team realised that planets c and d pass very close to each other as they trace their orbits. At their closest, they are only 1.5 million kilometres apart, which is 33 times closer than Mars and Earth ever get to each other. Each close passage between the planets produces a gravitational tug on planet d, making its orbit less circular and more elliptical. Along this elliptical path, planet d is slightly deformed every time it goes around the star. The astronomers computed that this deformation produces a lot of heat in the interior of the planet that needs to be transported to the surface via intense volcanic activity. Due to this phenomenon called tidal heating, LP 791-18 d is likely carpeted with volcanoes.
“The significant friction generated by tidal heating in the planet is responsible for heating its interior to a considerable extent, ultimately enabling the existence of a subsurface magma ocean,” explains Caroline Piaulet, a UdeM Ph.D. student who was involved in the discovery. “In our Solar System, we know that Jupiter’s moon Io is affected by Jupiter and its other moons in a similar way, and that world is the most volcanic we know.”
Planet d sits on the inner edge of the temperate (or “habitable”) zone, the traditional range of distances from a star where scientists hypothesise liquid water could exist on a planet’s surface. If the planet is as geologically active as UdeM’s team suspects, it could maintain an atmosphere. Given the right conditions, temperatures could even drop low enough on the planet’s night side for water to condense on the surface.
Measuring the masses of the planets
The proximity of Planets c and d also helped scientists measure their masses. When approached by Benneke with this discovery, many members of the TESS Follow-up Observing Program turned their ground-based telescopes to the LP 791-18 system, allowing them to collect observations of 67 transits from Planets c and d.
In these data, the team at UdeM was able to detect transit timing variations, which are slight differences in the exact times of the planets’ transits caused by the gravitational tug they exert on each other.
“This technique allowed us to estimate the masses of Planets c and d using only the transit data,” Piaulet explains. “By combining this information with the size of the planets – an information readily available from the same data – we can estimate the density of the planets and thus get an idea of their composition and nature.”
Comparing these values with planet interior models, astronomers were thus able to determine that the newly-found planet has a mass comparable to that of Earth. Its density is thus also consistent with a rocky composition like Earth. Planet c, which has a mass of about seven times that of Earth’s, has probably retained a significant amount of gas or lighter materials, akin to Neptune’s composition.
Planet c, the largest of the system, has already been approved for observing time on the Webb Telescope, as part of the Canadian NEAT program, dedicated to the study of exoplanets. Pierre-Alexis Roy, another Ph.D. student on Benneke’s team at UdeM, will be in charge of analysing these observations. “Having a precise constraint on the mass of Planet c will be crucial to analyse the substantial atmosphere we’re expecting to find on this mini-Neptune”, he explains.
In the future, the small size of the star may even allow the detection of a much less extended atmosphere on the newly found planet d. Scientists expect that an atmosphere like that of the Earth, Venus, or Saturn’s moon Titan could exist on Planet d. This system represents an unparalleled opportunity to learn more about small rocky planets, much like the TRAPPIST-1 system, which hosts seven Earth-sized planets, and is already being closely scrutinized by Webb.
“This system provides astronomers with a precious laboratory for testing various hypotheses related to the formation and evolution of terrestrial planets,” says Benneke. “The newly found planet d, an Earth-size world likely covered in volcanoes in a multiplanetary system, provides unprecedented opportunities to advance not only astronomy but many other fields of science, notably geology, planetary sciences, atmospheric sciences, and possibly astrobiology.”
About this study
“A temperate Earth-sized planet with tidally-heated interior transiting an M6 star” by Merrin Peterson et al., was published on May 17th, 2023, in Nature. In addition to Merrin Peterson, Björn Benneke, Caroline Piaulet, and Pierre-Alexis Roy, members of the Trottier Institute for Research on Exoplanets at Université de Montréal, the team also includes Jonathan Gagné, a UdeM Adjunct Professor, Scientific Advisor at the Space for Life Montreal Planetarium and member of iREx; Mohamad Ali-Dib, a former Trottier Postdoctoral Fellow at iREx, now at NYU Abu Dhabi; Ryan Cloutier, a former iREx graduate student and now Assistant Professor at McMaster University; Lauren Weiss, a former Trottier Postdoctoral Fellow at iREx who is now Assistant Professor at the University of Notre Dame as well as well as 66 other co-authors from the United States, France, Spain, Belgium, Japan, and Morocco.
NASA Goddard Space Flight Center and the Trottier Institute for Research on Exoplanets – Université de Montréal
Centre for Research in Astrophysics of Quebec
Björn Benneke (corresponding author)
About the Centre for Research in Astrophysics of Quebec
The Centre for Research in Astrophysics of Quebec (CRAQ) brings together all the astrophysicists in Quebec. Nearly 150 people, including some fifty researchers and their students from Université de Montréal, McGill University, Université Laval, Bishop’s University, Cégep de Sherbrooke, Collège de Bois-de-Boulogne and a number of other collaborating institutions are part of the cluster. The CRAQ is under the direction of Davif Lafrenière of the Université de Montréal. The CRAQ is one of the strategic clusters funded by the Fonds de recherche du Québec – Nature and Technologies (FRQNT).
Artistic representation of LP 791-18 d : 2048×1152 image
Legend : LP 791-18 d, illustrated here, is an Earth-size world only about 86 light-years away. The gravitational tug from a more massive planet in the system, shown as a blue dot in the background, may result in internal heating and volcanic eruptions – as much as Jupiter’s moon Io, the most geologically active body in the Solar System. Credit: NASA’s Goddard Space Flight Center/Chris Smith (KRBwyle)
Björn Benneke : photo
Legend: Björn Benneke, a Professor at the Université de Montréal and member of the Trottier Institute for Research on Exoplanets, whose team led this discovery. Credit : Amélie Philibert, Université de Montréal.
Caroline Piaulet : photo
Legend: Caroline Piaulet, a Ph.D. student at the Université de Montréal who worked on this discovery. Credit: Picture provided by Piaulet.