GRAVITY Instrument Breaks New Ground in Exoplanet Imaging

Cutting-edge VLTI instrument reveals details of a storm-wracked exoplanet using optical interferometry

Image: The GRAVITY instrument on ESO’s Very Large Telescope Interferometer (VLTI) has made the first direct observation of an exoplanet using optical interferometry. This method revealed a complex exoplanetary atmosphere with clouds of iron and silicates swirling in a planet-wide storm. The technique presents unique possibilities for characterising many of the exoplanets known today. This artist’s impression shows the observed exoplanet, which goes by the name HR8799e. Credit: ESO/L. Calçada.

The GRAVITY instrument on ESO’s Very Large Telescope Interferometer (VLTI) has made the first direct observation of an exoplanet using optical interferometry. This method revealed a complex exoplanetary atmosphere with clouds of iron and silicates swirling in a planet-wide storm. The technique presents unique possibilities for characterising many of the exoplanets known today.


 

SulutPos.com, Garching bei München, Germany – This result was announced today in a letter in the journal Astronomy and Astrophysics by the GRAVITY Collaboration [1], in which they present observations of the exoplanet HR8799e using optical interferometry. The exoplanet was discovered in 2010 orbiting the young main-sequence star HR8799, which lies around 129 light-years from Earth in the constellation of Pegasus.

HR 8799 in the constellation Pegasus. This chart shows the constellation of Pegasus, which depicts a winged horse from Greek mythology. The chart shows the location of HR8799 and marks most of the stars visible to the unaided eye on a clear dark night. The constellation is familiar to stargazers as it contains three of the four stars that make up the bright asterism known as the Square of Pegasus, used to locate various objects in the sky. The constellation also contains multiple deep-sky objects of interest to astronomers, including the gravitationally lensed quasar known as Einstein’s Cross. Credit: ESO, IAU and Sky & Telescope
HR 8799 in the constellation Pegasus. This chart shows the constellation of Pegasus, which depicts a winged horse from Greek mythology. The chart shows the location of HR8799 and marks most of the stars visible to the unaided eye on a clear dark night. The constellation is familiar to stargazers as it contains three of the four stars that make up the bright asterism known as the Square of Pegasus, used to locate various objects in the sky. The constellation also contains multiple deep-sky objects of interest to astronomers, including the gravitationally lensed quasar known as Einstein’s Cross. Credit: ESO, IAU and Sky & Telescope.

Today’s result, which reveals new characteristics of HR8799e, required an instrument with very high resolution and sensitivity. GRAVITY can use ESO’s VLT’s four unit telescopes to work together to mimic a single larger telescope using a technique known as interferometry [2]. This creates a super-telescope — the VLTI  — that collects and precisely disentangles the light from HR8799e’s atmosphere and the light from its parent star [3].

HR8799e is a ‘super-Jupiter’, a world unlike any found in our Solar System, that is both more massive and much younger than any planet orbiting the Sun. At only 30 million years old, this baby exoplanet is young enough to give scientists a window onto the formation of planets and planetary systems. The exoplanet is thoroughly inhospitable — leftover energy from its formation and a powerful greenhouse effect heat HR8799e to a hostile temperature of roughly 1000 °C.

Surroundings of the star HR 8799. This wide-field image shows the surroundings of the young star HR8799 in the constellation of Pegasus. This picture was created from material forming part of the Digitized Sky Survey 2. The location of HR 8799 is shown. Credit: ESO/Digitized Sky Survey 2
Surroundings of the star HR 8799. This wide-field image shows the surroundings of the young star HR8799 in the constellation of Pegasus. This picture was created from material forming part of the Digitized Sky Survey 2. The location of HR 8799 is shown. Credit: ESO/Digitized Sky Survey 2.

This is the first time that optical interferometry has been used to reveal details of an exoplanet, and the new technique furnished an exquisitely detailed spectrum of unprecedented quality — ten times more detailed than earlier observations. The team’s measurements were able to reveal the composition of HR8799e’s atmosphere  — which contained some surprises.

“Our analysis showed that HR8799e has an atmosphere containing far more carbon monoxide than methane — something not expected from equilibrium chemistry,” explains team leader Sylvestre Lacour researcher CNRS at the Observatoire de Paris – PSL and the Max Planck Institute for Extraterrestrial Physics. “We can best explain this surprising result with high vertical winds within the atmosphere preventing the carbon monoxide from reacting with hydrogen to form methane.”

Aerial view of the VLTI with tunnels superimposed. Aerial view of the observing platform on the top of Paranal mountain (from late 1999), with the four enclosures for the 8.2-m Unit Telescopes (UTs) and various installations for the VLT Interferometer (VLTI). Three 1.8-m VLTI Auxiliary Telescopes (ATs) and paths of the light beams have been superimposed on the photo. Also seen are some of the 30 "stations" where the ATs will be positioned for observations and from where the light beams from the telescopes can enter the Interferometric Tunnel below. The straight structures are supports for the rails on which the telescopes can move from one station to another. The Interferometric Laboratory (partly subterranean) is at the centre of the platform. Credit: ESO
Aerial view of the VLTI with tunnels superimposed. Aerial view of the observing platform on the top of Paranal mountain (from late 1999), with the four enclosures for the 8.2-m Unit Telescopes (UTs) and various installations for the VLT Interferometer (VLTI). Three 1.8-m VLTI Auxiliary Telescopes (ATs) and paths of the light beams have been superimposed on the photo. Also seen are some of the 30 “stations” where the ATs will be positioned for observations and from where the light beams from the telescopes can enter the Interferometric Tunnel below. The straight structures are supports for the rails on which the telescopes can move from one station to another. The Interferometric Laboratory (partly subterranean) is at the centre of the platform.
Credit: ESO.

The team found that the atmosphere also contains clouds of iron and silicate dust. When combined with the excess of carbon monoxide, this suggests that HR8799e’s atmosphere is engaged in an enormous and violent storm.

“Our observations suggest a ball of gas illuminated from the interior, with rays of warm light swirling through stormy patches of dark clouds,” elaborates Lacour. “Convection moves around the clouds of silicate and iron particles, which disaggregate and rain down into the interior. This paints a picture of a dynamic atmosphere of a giant exoplanet at birth, undergoing complex physical and chemical processes.”

VLT interferometer principle. Schematic lay-out of the VLT Interferometer. The light from a distant celestial objects enters two of the VLT telescopes and is reflected by the various mirrors into the Interferometric Tunnel, below the observing platform on the top of Paranal. Two Delay Lines with moveable carriages continuously adjust the length of the paths so that the two beams interfere constructively and produce fringes at the interferometric focus in the laboratory. Credit: ESO
VLT interferometer principle. Schematic lay-out of the VLT Interferometer. The light from a distant celestial objects enters two of the VLT telescopes and is reflected by the various mirrors into the Interferometric Tunnel, below the observing platform on the top of Paranal. Two Delay Lines with moveable carriages continuously adjust the length of the paths so that the two beams interfere constructively and produce fringes at the interferometric focus in the laboratory. Credit: ESO.

This result builds on GRAVITY’s string of impressive discoveries, which have included breakthroughs such as last year’s observation of gas swirling at 30% of the speed of light just outside the event horizon of the massive Black Hole in the Galactic Centre. It also adds a new way of observing exoplanets to the already extensive arsenal of methods available to ESO’s telescopes and instruments — paving the way to many more impressive discoveries [4].

ESOcast 197 Light: GRAVITY uncovers stormy exoplanet skies

Notes

[1] GRAVITY was developed by a collaboration consisting of the Max Planck Institute for Extraterrestrial Physics (Germany), LESIA of Paris Observatory–PSL / CNRS / Sorbonne Université / Univ. Paris Diderot and IPAG of Université Grenoble Alpes / CNRS (France), the Max Planck Institute for Astronomy (Germany), the University of Cologne (Germany), the CENTRA–Centro de Astrofisica e Gravitação (Portugal) and ESO.

[2] Interferometry is a technique that allows astronomers to create a super-telescope by combining several smaller telescopes. ESO’s VLTI is an interferometric telescope created by combining two or more of the Unit Telescopes (UTs) of the Very Large Telescope or all four of the smaller Auxiliary Telescopes. While each UT has an impressive 8.2-m primary mirror, combining them creates a telescope with 25 times more resolving power than a single UT observing in isolation.

[3] Exoplanets can be observed using many different methods. Some are indirect, such as the radial velocity method used by ESO’s exoplanet-hunting HARPS instrument, which measures the pull a planet’s gravity has on its parent star. Direct methods, like the technique pioneered for this result, involve observing the planet itself instead of its effect on its parent star.

[4] Recent exoplanet discoveries made using ESO telescopes include last year’s successful detection of a super-Earth orbiting Barnard’s Star, the closest single star to our Sun, and ALMA’s discovery of young planets orbiting an infant star, which used another novel technique for planet detection.

More information

This research was presented in the paper “First direct detection of an exoplanet by optical interferometry” in Astronomy and Astrophysics.

The team was composed of :  S. Lacour (LESIA, Observatoire de Paris – PSL, CNRS, Sorbonne Universités, UPMC Univ. Paris 06, Univ. Paris Diderot, Meudon, France [LESIA]; Max Planck Institute for Extraterrestrial Physics, Garching, Germany [MPE]), M. Nowak (LESIA), J. Wang (Department of Astronomy, California Institute of Technology, Pasadena, USA), O. Pfuhl (MPE), F. Eisenhauer (MPE), R. Abuter (ESO, Garching, Germany), A. Amorim (Universidade de Lisboa, Lisbon, Portugal; CENTRA – Centro de Astrofísica e Gravitação, IST, Universidade de Lisboa, Lisbon, Portugal), N. Anugu (Faculdade de Engenharia, Universidade do Porto, Porto, Portugal; School of Physics, Astrophysics Group, University of Exeter, Exeter, United Kingdom), M. Benisty (Univ. Grenoble Alpes, CNRS, IPAG, Grenoble, France [IPAG]), J.P. Berger (IPAG), H. Beust (IPAG), N. Blind (Observatoire de Genève, Université de Genève, Versoix, Switzerland), M. Bonnefoy (IPAG), H. Bonnet (ESO, Garching, Germany), P. Bourget (ESO, Santiago, Chile), W. Brandner (Max Planck Institute for Astronomy, Heidelberg, Germany [MPIA]), A. Buron (MPE), C. Collin (LESIA), B. Charnay (LESIA), F. Chapron (LESIA) , Y. Clénet (LESIA), V. Coudé du Foresto (LESIA), P.T. de Zeeuw (MPE; Sterrewacht Leiden, Leiden University, Leiden, The Netherlands), C. Deen (MPE), R. Dembet (LESIA), J. Dexter (MPE), G. Duvert (IPAG), A. Eckart (1st Institute of Physics, University of Cologne, Cologne, Germany;  Max Planck Institute for Radio Astronomy, Bonn, Germany), N.M. Förster Schreiber (MPE), P. Fédou (LESIA), P. Garcia (Faculdade de Engenharia, Universidade do Porto, Porto, Portugal; ESO, Santiago, Chile; CENTRA – Centro de Astrofísica e Gravitação, IST, Universidade de Lisboa, Lisbon, Portugal), R. Garcia Lopez (Dublin Institute for Advanced Studies, Dublin, Ireland; MPIA), F. Gao (MPE), E. Gendron (LESIA), R. Genzel (MPE; Departments of Physics and Astronomy, University of California, Berkeley, USA), S. Gillessen (MPE), P. Gordo (Universidade de Lisboa, Lisbon, Portugal; CENTRA – Centro de Astrofísica e Gravitação, IST, Universidade de Lisboa, Lisbon, Portugal), A. Greenbaum (Department of Astronomy, University of Michigan, Ann Arbor, USA), M. Habibi (MPE), X. Haubois (ESO, Santiago, Chile), F. Haußmann (MPE), Th. Henning (MPIA), S. Hippler (MPIA), M. Horrobin (1st Institute of Physics, University of Cologne, Cologne, Germany), Z. Hubert (LESIA), A. Jimenez Rosales (MPE), L. Jocou (IPAG), S. Kendrew (European Space Agency, Space Telescope Science Institute, Baltimore, USA; MPIA), P. Kervella (LESIA), J. Kolb (ESO, Santiago, Chile), A.-M. Lagrange (IPAG), V. Lapeyrère (LESIA), J.-B. Le Bouquin (IPAG), P. Léna (LESIA), M. Lippa (MPE), R. Lenzen (MPIA), A.-L. Maire (STAR Institute, Université de Liège, Liège, Belgium; MPIA), P. Mollière (Sterrewacht Leiden, Leiden University, Leiden, The Netherlands), T. Ott (MPE), T. Paumard (LESIA), K. Perraut (IPAG), G. Perrin (LESIA), L. Pueyo (Space Telescope Science Institute, Baltimore, USA), S. Rabien (MPE), A. Ramírez (ESO, Santiago, Chile), C. Rau (MPE), G. Rodríguez-Coira (LESIA), G. Rousset (LESIA), J. Sanchez-Bermudez (Instituto de Astronomía, Universidad Nacional Autónoma de México, Mexico City, Mexico; MPIA), S. Scheithauer (MPIA), N. Schuhler (ESO, Santiago, Chile), O. Straub (LESIA; MPE), C. Straubmeier (1st Institute of Physics, University of Cologne, Cologne, Germany), E. Sturm (MPE), L.J. Tacconi (MPE), F. Vincent (LESIA), E.F. van Dishoeck (MPE; Sterrewacht Leiden, Leiden University, Leiden, The Netherlands), S. von Fellenberg (MPE), I. Wank (1st Institute of Physics, University of Cologne, Cologne, Germany), I. Waisberg (MPE) , F. Widmann (MPE), E. Wieprecht (MPE), M. Wiest (1st Institute of Physics, University of Cologne, Cologne, Germany), E. Wiezorrek (MPE), J. Woillez (ESO, Garching, Germany), S. Yazici (MPE; 1st Institute of Physics, University of Cologne, Cologne, Germany), D. Ziegler (LESIA), and G. Zins (ESO, Santiago, Chile).

ESO is the foremost intergovernmental astronomy organisation in Europe and the world’s most productive ground-based astronomical observatory by far. It has 16 Member States: Austria, Belgium, the Czech Republic, Denmark, France, Finland, Germany, Ireland, Italy, the Netherlands, Poland, Portugal, Spain, Sweden, Switzerland and the United Kingdom, along with the host state of Chile and with Australia as a Strategic Partner. ESO carries out an ambitious programme focused on the design, construction and operation of powerful ground-based observing facilities enabling astronomers to make important scientific discoveries.

ESO also plays a leading role in promoting and organising cooperation in astronomical research. ESO operates three unique world-class observing sites in Chile: La Silla, Paranal and Chajnantor. At Paranal, ESO operates the Very Large Telescope and its world-leading Very Large Telescope Interferometer as well as two survey telescopes, VISTA working in the infrared and the visible-light VLT Survey Telescope. Also at Paranal ESO will host and operate the Cherenkov Telescope Array South, the world’s largest and most sensitive gamma-ray observatory. ESO is also a major partner in two facilities on Chajnantor, APEX and ALMA, the largest astronomical project in existence. And on Cerro Armazones, close to Paranal, ESO is building the 39-metre Extremely Large Telescope, the ELT, which will become “the world’s biggest eye on the sky”.

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