DOCSLIB.ORG

Exoplanets : the Beta Pictoris System Is Unveiled

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Exoplanets : the Beta Pictoris System Is Unveiled Exoplanets : the beta Pictoris system is unveiled https://achats-publics.obspm.fr/exoplanets-the-beta-pictoris.html Press release | CNRS Exoplanets : the beta Pictoris system is unveiled Date de mise en ligne : mardi 6 octobre 2020 Observatoire de Paris - PSL Centre de recherche en astronomie et astrophysique Copyright © Observatoire de Paris - PSL Centre de recherche en astronomie et astrophysique Page 1/3 Exoplanets : the beta Pictoris system is unveiled Researchers from CNRS, Paris Observatory - PSL, Grenoble Alpes University, Aix-Marseille University, Paris University, Lille University and their foreign partners have just detected for the first time the light emitted by the exoplanet ² Pictoris c, previously revealed thanks to the small variations it prints on the speed of the star of the same name. The very precise estimation of its position made it possible to point the GRAVITY interferometer at it, using four ground-based telescopes in Chile simultaneously, and thus to observe it directly. These results are published in two articles in the journal Astronomy & Astrophysics on October 2, 2020. Images synthétiques du système planétaire beta Pictoris. A gauche et au centre, vue du système avec l'étoile et son disque de poussières. Les orbites des deux planètes sont représentées, vue du dessus dans l'image de droite.( © Max-Planck-Institut für Astronomie Since August 2019, we knew of its existence, the period of its orbit, and even its mass, but it was still escaping our gaze. The presence of ² Pictoris c had been betrayed after more than 10 years of observations of its eponymous star thanks to an indirect method called radial velocities : the small displacements of the star indeed show that a giant planet weighing the equivalent of nine Jupiter is very close to it, at only 2.7 astronomical units [1]. So close that it had not yet been possible to observe it directly, since classical telescopes were unable to distinguish it from the radiation of its star. But using the GRAVITY interferometer, whose accuracy is 100 times higher than that of conventional telescopes, the international research team [2]2 was able to capture for the first time the light emitted by ² Pictoris c. This feat would not have been possible without the very precise calculations of the position of the exoplanet around its star. Indeed, GRAVITY is very sensitive, but its field of view is very small. It was thus necessary that the estimation of the position of ² Pictoris c be precise to be able to point the telescopes at the right place. This is the first time that a direct observation of an exoplanet is based on data provided by the radial velocity method. Scientists have therefore been able to combine the information offered by these two techniques : one gives mass and the other luminosity. These data are of primary interest because the exact relationship between the mass and luminosity of planets is linked to the mechanisms of their formation. Copyright © Observatoire de Paris - PSL Centre de recherche en astronomie et astrophysique Page 2/3 Exoplanets : the beta Pictoris system is unveiled Thus, the research team was able to confirm that the young planet ² Pictoris c is cooling down and still expelling part of the thermal energy accumulated during its formation. These observations obtained on a young planet will allow a better understanding of how giant planets are formed. The scientists also hope to be able to answer a new question raised by their study : why is ² Pictoris c six times less luminous than its sister planet ² Pictoris b, when their masses are very close ? Bibliographie Unveiling the beta Pictoris system, coupling high contrast imaging, interferometric, and radial velocity data. A-M Lagrange et al. Astronomy & Astrophysics, le 2 octobre 2020. DOI:10.1051/0004-6361/202038823 Direct confirmation of the radial-velocity planet ² Pic c. M. Nowak et al. Astronomy & Astrophysics, le 2 octobre 2020. DOI:10.1051/0004-6361/202039039 [1] One astronomical unit is equivalent to the distance Earth-Sun, about 150 million kilometers. While its big sister ² Pictoris b is seen evolving at the same distance as Saturn around the Sun, ² Pictoris c evolves on an orbit equivalent to that of the asteroid belt in the solar system, between Mars and Jupiter [2] In France, researchers from the Laboratoire d'études spatiales et d'instrumentation en astrophysique (Observatoire de Paris - PSL/CNRS/Sorbonne Université/Université de Paris), the Institut de planétologie et d'astrophysique de Grenoble (CNRS/Université Grenoble Alpes) participated in this work, the Astrophysics Laboratory of Marseille (CNRS/CNES/Aix-Marseille University), the Astrophysics Research Center of Lyon (CNRS/ENS de Lyon/Université Claude Bernard Lyon 1), the laboratory Galaxies, étoiles, physique, instrumentation (Observatoire de Paris - PSL/CNRS), of the Institut de mécanique céleste et de calcul des éphémérides (Observatoire de Paris - PSL/CNRS/Sorbonne Université/Université de Lille) and of the Laboratoire franco-chilien d'astronomie (CNRS/Universidad de Concepcion/Pontificia universidad catolica de Chile/Universidad de Chile). Copyright © Observatoire de Paris - PSL Centre de recherche en astronomie et astrophysique Page 3/3.
Load more

Recommended publications
  • RADIAL VELOCITIES in the ZODIACAL DUST CLOUD
    A SURVEY OF RADIAL VELOCITIES in the ZODIACAL DUST CLOUD Brian Harold May Astrophysics Group Department of Physics Imperial College London Thesis submitted for the Degree of Doctor of Philosophy to Imperial College of Science, Technology and Medicine London · 2007 · 2 Abstract This thesis documents the building of a pressure-scanned Fabry-Perot Spectrometer, equipped with a photomultiplier and pulse-counting electronics, and its deployment at the Observatorio del Teide at Izaña in Tenerife, at an altitude of 7,700 feet (2567 m), for the purpose of recording high-resolution spectra of the Zodiacal Light. The aim was to achieve the first systematic mapping of the MgI absorption line in the Night Sky, as a function of position in heliocentric coordinates, covering especially the plane of the ecliptic, for a wide variety of elongations from the Sun. More than 250 scans of both morning and evening Zodiacal Light were obtained, in two observing periods – September-October 1971, and April 1972. The scans, as expected, showed profiles modified by components variously Doppler-shifted with respect to the unshifted shape seen in daylight. Unexpectedly, MgI emission was also discovered. These observations covered for the first time a span of elongations from 25º East, through 180º (the Gegenschein), to 27º West, and recorded average shifts of up to six tenths of an angstrom, corresponding to a maximum radial velocity relative to the Earth of about 40 km/s. The set of spectra obtained is in this thesis compared with predictions made from a number of different models of a dust cloud, assuming various distributions of dust density as a function of position and particle size, and differing assumptions about their speed and direction.
    [Show full text]
  • 1 Director's Message
    1 Director’s Message Markus Kissler-Patig 3 Weighing the Black Hole in M101 ULX-1 Stephen Justham and Jifeng Liu 8 World’s Most Powerful Planet Finder Turns its Eye to the Sky: First Light with the Gemini Planet Imager Bruce Macintosh and Peter Michaud 12 Science Highlights Nancy A. Levenson 15 Operations Corner: Update and 2013 Review Andy Adamson 20 Instrumentation Development: Update and 2013 Review Scot Kleinman ON THE COVER: GeminiFocus January 2014 The cover of this issue GeminiFocus is a quarterly publication of Gemini Observatory features first light images from the Gemini 670 N. A‘ohoku Place, Hilo, Hawai‘i 96720 USA Planet Imager that Phone: (808) 974-2500 Fax: (808) 974-2589 were released at the Online viewing address: January 2014 meeting www.gemini.edu/geminifocus of the American Managing Editor: Peter Michaud Astronomical Society Science Editor: Nancy A. Levenson held in Washington, D.C. Associate Editor: Stephen James O’Meara See the press release Designer: Eve Furchgott / Blue Heron Multimedia that accompanied the images starting on Any opinions, findings, and conclusions or recommendations page 8 of this issue. expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation. Markus Kissler-Patig Director’s Message 2013: A Successful Year for Gemini! As 2013 comes to an end, we can look back at 12 very successful months for Gemini despite strong budget constraints. Indeed, 2013 was the first stage of our three-year transition to a reduced opera- tions budget, and it was marked by a roughly 20 percent cut in contributions from Gemini’s partner countries.
    [Show full text]
  • Disks in Nearby Planetary Systems with JWST and ALMA
    Disks in Nearby Planetary Systems with JWST and ALMA Meredith A. MacGregor NSF Postdoctoral Fellow Carnegie Department of Terrestrial Magnetism 233rd AAS Meeting ExoPAG 19 January 6, 2019 MacGregor Circumstellar Disk Evolution molecular cloud 0 Myr main sequence star + planets (?) + debris disk (?) Star Formation > 10 Myr pre-main sequence star + protoplanetary disk Planet Formation 1-10 Myr MacGregor Debris Disks: Observables First extrasolar debris disk detected as “excess” infrared emission by IRAS (Aumann et al. 1984) SPHERE/VLT Herschel ALMA VLA Boccaletti et al (2015), Matthews et al. (2015), MacGregor et al. (2013), MacGregor et al. (2016a) Now, resolved at wavelengthsfrom from Herschel optical DUNES (scattered light) to millimeter and radio (thermal emission) MacGregor Planet-Disk Interactions Planets orbiting a star can gravitationally perturb an outer debris disk Expect to see a variety of structures: warps, clumps, eccentricities, central offsets, sharp edges, etc. Goal: Probe for wide separation planets using debris disk structure HD 15115 β Pictoris Kuiper Belt Asymmetry Warp Resonance Kalas et al. (2007) Lagrange et al. (2010) Jewitt et al. (2009) MacGregor Debris Disks Before ALMA Epsilon Eridani HD 95086 Tau Ceti Beta PictorisHR 4796A HD 107146 AU Mic Greaves+ (2014) Su+ (2015) Lawler+ (2014) Vandenbussche+ (2010) Koerner+ (1998) Hughes+ (2011) Matthews+ (2015) 49 Ceti HD 181327 HD 21997 Fomalhaut HD 10647 (q1 Eri) Eta Corvi HR 8799 Roberge+ (2013) Lebreton+ (2012) Moor+ (2015) Acke+ (2012) Liseau+ (2010) Lebreton+ (2016)
    [Show full text]
  • Cycle 14 Approved Programs
    Cycle 14 Approved Programs as of 04/05/05 Science First Name Last Name Type Phase II ID Institution Country Title Category Physical Processes in Orion's Veil: A High Resolution Nicholas Abel AR 10636 University of Kentucky USA Star Formation UV Absorption Study of the Line of Sight Towards the Trapezium University of Eric Agol GO 10486 USA Cosmology A Cosmic String Lens Candidate Washington University of Eric Agol AR 10637 USA Cool Stars Finding Terrestrial Planets with HST Washington Space Telescope NGC 4449: a Testbed for Starbursts in the Low- and Alessandra Aloisi GO 10585 Science Institute - USA Galaxies High-Redshift Universe ESA Space Telescope The Rosetta Stone without a Distance: Hunting for Alessandra Aloisi GO 10586 Science Institute - USA Galaxies Cepheids in the "Primordial" Galaxy I Zw 18 ESA University of Timing Studies of the X-ray Binary Populations in Scott Anderson GO 10615 USA Hot Stars Washington Globular Clusters The Johns Hopkins A Search for Debris Disks in the Coeval Beta Pictoris David Ardila GO 10487 USA Star Formation University Moving Group University of Colorado Thomas Ayres AR 10638 USA Cool Stars StarCAT at Boulder Studies of Europa's Plasma Interactions and Gilda Ballester AR 10639 University of Arizona USA Solar System Atmosphere with HST/STIS FUV Images Edward Baltz GO 10543 Stanford University USA Galaxies Microlensing in M87 and the Virgo Cluster University of HST Observations of MilliJansky Radio Sources from the Robert Becker AR 10640 USA Galaxies California - Davis VLA FIRST Survey European Southern
    [Show full text]
  • Signatures of Giant Planets on the Solar System Kuiper Belt Dust Disk and Implications for Extrasolar Planet in Epsilon Eridani
    Lunar and Planetary Science XXX 1698.pdf SIGNATURES OF GIANT PLANETS ON THE SOLAR SYSTEM KUIPER BELT DUST DISK AND IMPLICATIONS FOR EXTRASOLAR PLANET IN EPSILON ERIDANI. J.-C. Liou1 and H. A. Zook2, 1GB Tech/Lockheed Martin, C104 Lockheed Martin, 2400 NASA Rd. One, Houston, TX 77058, 2SN2, NASA Johnson Space Center, Houston, TX 77052. Summary: One method to detect extrasolar Dust disks in Beta Pictoris, Epsilon Eridani, planetary systems is to deduce the perturbations of and other systems are analogues to our Solar Sys- planets on the observed circumstellar dust disks. tem’s Kuiper Belt dust disk. Therefore, it is of Our Solar System, with its known configuration of great interest to understanding how the Kuiper planets, provide an excellent example to study how Belt IDP distribution is affected by the giant plan- the distribution of dust particles is affected by the ets in our Solar System. We have numerically existence of different planets. Numerical simula- simulated the orbital evolution of Kuiper Belt tions of the orbital evolution of dust particles from IDPs, including gravitational perturbations from 7 Kuiper Belt objects show that the four giant plan- planets (Mercury and Pluto are not included due to ets, especially Neptune and Jupiter, impose distinct their small masses), solar radiation pressure, and and dramatic signatures on the overall distribution PR and solar wind drag. Dust particles range from of Kuiper belt dust particles. The signatures are 3 to 23 micrometers in diameter. For a given size, very similar to those observed in Epsilon Eridani. 100 IDPs are included in the simulations.
    [Show full text]
  • Extrasolar Systems Shed Light on Our
    NEWS FEATURE NEWS FEATURE Extrasolar systems shed light on our own Amazing as the discoveries of planets, comets, and asteroid belts around other stars are, it’s their potential to shed light on our Solar System’s origins that is exciting astronomers. Nadia Drake broader sense, we’re trying to understand Science Writer if our own world—and our own Solar Sys- tem—is ‘normal,’” says David Grinspoon, Chair of Astrobiology at the US Library of A planet smaller than Mercury circles a star astronomers can use the Solar System’s ar- Congress in Washington, DC, “or, in some 210 light-years away. Around another star, chitecture to predict the presence of un- extraordinary way, abnormal.” two planets live so close together that each seen objects in these systems, and use the periodically rises in the other’s sky. Other systems to learn more about the celestial Chasing Comets alien skies are home to two suns that rise events that gave birth to and shaped our One stellar system with a recently identified and set, casting double shadows over their Solar System. kinship to ours is that of Vega. This famil- double-sunned worlds. Planets so dense “We definitely learn more about the Solar iar star burns brightly in the northern sky, they might have diamond rinds, worlds System’s past and future by observing other where it forms a summertime triangle with whose year is shorter than an Earthday, oth- stellar systems,” says astronomer Kate Su stars Deneb and Altair. Just 25 light-years ers that orbit their star backward—the cos- of the University of Arizona, Tucson, AZ.
    [Show full text]
  • Spectral Classification of Stars
    29:50 Astronomy Lab #6 Stars, Galaxies, and the Universe Name Partner(s) Date Grade Category Max Points Points Received On Time 5 Printed Copy 5 Lab Work 90 Total 100 Spectral Classification of Stars 1. Introduction Scientists across all fields use classification systems to help them sub-divide the vast universe of objects and phenomena into smaller groups, making them easier to study. In biology, life can be categorized by cellular properties. Animals are separated from plants, cats separated from dogs, oak trees separated from pine trees, etc. This framework allows biologists to better understand how processes are FIGURE 1: SPECTRUM OF VEGA interconnected and quickly predict characteristics of newly discovered species. In Astronomy, the stellar classification system allows scientists to understand the p r o p e r t i e s o f s t a r s . E a r l y astronomers began to realize that the extensive number of stars exhibited patterns related to the starʼs color and temperature. This classification was good, but had limitations (especially for studying distant stars). By the early 1900ʼs, a classification system based on the observed stellar spectra was developed and is still used today. A STELLAR SPECTRUM is a measurement of a 1 Spectral Classification of Stars starʼs brightness across of range of wavelengths (or frequencies). It is in a sense a “fingerprint” for the star, containing features that reveal the chemical composition, age, and temperature. This measurement is made by “breaking up” the light from the star into individual wavelengths, much like how a prism or a raindrop separates the sunlight into a rainbow.
    [Show full text]
  • 1411 (Created: Wednesday, June 24, 2020 at 12:00:37 AM Eastern Standard Time) - Overview
    JWST Proposal 1411 (Created: Wednesday, June 24, 2020 at 12:00:37 AM Eastern Standard Time) - Overview 1411 - Coronagraphy of the Debris Disk Archetype Beta Pictoris Cycle: 1, Proposal Category: GTO INVESTIGATORS Name Institution E-Mail Dr. Christopher C. Stark (PI) Space Telescope Science Institute [email protected] Dr. Laurent Pueyo (CoI) Space Telescope Science Institute [email protected] Dr. Marshall Perrin (CoI) Space Telescope Science Institute [email protected] Dr. Remi Soummer (CoI) Space Telescope Science Institute [email protected] Dr. Matt Mountain (CoI) Space Telescope Science Institute [email protected] Abhijith Rajan (CoI) Space Telescope Science Institute [email protected] Dr. Mark Clampin (CoI) NASA Goddard Space Flight Center [email protected] OBSERVATIONS Folder Observation Label Observing Template Science Target Beta Pic with MIRI coronagraphs 1 Beta Pic - 2300 Lyot R MIRI Coronagraphic Imaging (1) BETA-PIC oll 1 2 Beta Pic - 1550 4QPM MIRI Coronagraphic Imaging (1) BETA-PIC Roll 1 3 Beta Pic - 1550 4QPM MIRI Coronagraphic Imaging (1) BETA-PIC Roll 2 4 Beta Pic - 2300 Lyot R MIRI Coronagraphic Imaging (1) BETA-PIC oll 2 5 Alpha Pic - 2300 Lyot MIRI Coronagraphic Imaging (2) ALPHA-PIC PSF 6 Alpha Pic - 1550 4QP MIRI Coronagraphic Imaging (2) ALPHA-PIC M PSF Beta Pic with NIRCam Coronagraphs 7 Alpha Pic - LW PSF NIRCam Coronagraphic Imaging (2) ALPHA-PIC 1 JWST Proposal 1411 (Created: Wednesday, June 24, 2020 at 12:00:37 AM Eastern Standard Time) - Overview Folder Observation Label Observing Template Science Target 8 Alpha Pic - SW PSF NIRCam Coronagraphic Imaging (2) ALPHA-PIC 10 Beta Pic - SW Roll 1 NIRCam Coronagraphic Imaging (1) BETA-PIC 11 Beta Pic - SW Roll 2 NIRCam Coronagraphic Imaging (1) BETA-PIC 12 Beta Pic - LW Roll 2 NIRCam Coronagraphic Imaging (1) BETA-PIC 13 Beta Pic - LW Roll 1 NIRCam Coronagraphic Imaging (1) BETA-PIC ABSTRACT The famous debris disk around Beta Pic was the first circumstellar disk to be spatially resolved.
    [Show full text]
  • A1 F2015 Review Copy.Key
    Review Astronomy 1 — Elementary Astronomy LA Mission College Spring F2015 Quotes & Cartoon of the Day “One may wonder, What came before? If space-time did not exist then, how could everything appear from nothing? . Explaining this initial singularity—where and when it all began—still remains the most intractable problem of modern cosmology. — Andrei Linde “But who shall dwell in these worlds if they be inhabited? ... Are we or they Lords of the World? ... And how are all things made for man?” — Johannes Kepler “Our sun is one of 100 billion stars in our galaxy. Our galaxy is one of billions of galaxies populating the universe. It would be the height of presumption to think that we are the only living things in that enormous immensity.” — Wernher von Braun Astronomy 1 - Elementary Astronomy LA Mission College Levine F2015 Announcements • Observing Project & Extra Credit Due • Midterm graded & gradebook updated to drop lowest • remainder of grading (hopefully) updated this weekend • Final 12/15 at 10-12 AM! Astronomy 1 - Elementary Astronomy LA Mission College Levine F2015 Last Class • Debrief Midterm • Debrief LT • Cosmology & Fate of the Universe • Exoplanets (time permitting) Astronomy 1 - Elementary Astronomy LA Mission College Levine F2015 This Class • Review/Debrief Midterm • Exoplanets (time permitting) Astronomy 1 - Elementary Astronomy LA Mission College Levine F2015 About the Final Astronomy 1 — Elementary Astronomy LA Mission College Spring F2015 About the Final • Similar format to Midterms • Similar length • a little longer,
    [Show full text]
  • New Planet Discovered in Orbit of Young Milky Way Star 19 August 2019
    New planet discovered in orbit of young Milky Way star 19 August 2019 roughly every 1,200 days. Like its big sister ? Pictoris b, discovered by Lagrange and her team in 2009, it is a gassy giant. Visible with the naked eye, Beta Pictoris—with a mass nearly twice that of the Sun—is a newborn by comparison: only 23 million years old. The Sun is more than 4.5 billion years old. It is also relatively nearby, just over 63 light years, and surrounded by a disk of stellar dust. This swirling halo of debris and gas was the first such configuration to be captured in image, making Beta Pictoris a celebrity star in the 1980s. "To better understand the early stage of formation and evolution, this is probably the best planetary system we know of," Lagrange told AFP. At least two giant planets, aged 20 million years at most, Observations show that the two planets are still orbit around the star (which is hidden): ? Pictoris c, the taking shape. nearest one, which has just been discovered, and ? Pictoris b, which is more distant. The disk of dust and gas can be seen in the background. Credit: P Rubini / AM Lagrange A second planet has been discovered circling Beta Pictoris, a fledgling star in our own galaxy offering astronomers a rare glimpse of a planetary system in the making, according to a study published Monday. "We talking about a giant planet about 3,000 times more massive than Earth, situated 2.7 times further from its star than the Earth is from the Sun," said Anne-Marie Lagrange, an astronomer at France's National Centre for Scientific Research and lead The disk of dust surrounding ? Pictoris and the position of author of a study in Nature Astronomy.
    [Show full text]
  • Observation of Circumstellar Disks: Dust and Gas Components
    Dutrey et al.: Gas and Dust Components of Circumstellar Disks 81 Observation of Circumstellar Disks: Dust and Gas Components Anne Dutrey Observatoire de Bordeaux Alain Lecavelier des Etangs Institut d’Astrophysique de Paris Jean-Charles Augereau Service D’Astrophysique du CEA-Saclay and Institut d’Astrophysique de Paris Since the 1990s, protoplanetary disks and planetary disks have been intensively observed from optical to the millimeter wavelengths, and numerous models have been developed to in- vestigate their gas and dust properties and dynamics. These studies remain empirical and rely on poor statistics, with only a few well-known objects. However, the late phases of the stellar formation are among the most critical for the formation of planetary systems. Therefore, we believe it is timely to tentatively summarize the observed properties of circumstellar disks around young stars from the protoplanetary to the planetary phases. Our main goal is to present the physical properties that are considered to be observationally robust and to show their main physical differences associated with an evolutionary scheme. We also describe areas that are still poorly understood, such as how protoplanetary disks disappear, leading to planetary disks and eventually planets. 1. INTRODUCTION protoplanetary disks. During this phase, the dust emission is optically thick in the near-IR (NIR) and the central young Before the 1980s, the existence of protoplanetary disks of star still accretes from its disk. Such disks are also naturally gas and dust around stars similar to the young Sun (4.5 b.y. called accretion disks. ago) was inferred from the theory of stellar formation (e.g., On the other hand, images of β Pictoris by Smith and Shakura and Suynaev, 1973), the knowledge of our own Terrile (1984) demonstrated that Vega-type stars or old PMS planetary system, and dedicated models of the protosolar stars can also be surrounded by optically thin dusty disks.
    [Show full text]
  • Astrotalk: Behind the News Headlines of May 2017
    AstroTalk: Behind the news headlines of May 2017 Richard de Grijs (何锐思) (Kavli Institute for Astronomy and Astrophysics, Peking University) Planetary formation is disks of dust and gas unveiled Newborn stars are typically located in disks of gas and dust. When planets first begin to form, rings of rocky and icy material (‘planetesimals’) form. The dust in those rings starts to stick together, growing until clumps develop that are large enough to attract other clumps because of their gravity. Astronomers believe that the process of forming planets and dissipating the disk takes about 10 million years. Many mysteries remain, however, including the tendency of dust not to stick together, and the likelihood that colliding clumps could break apart rather than agglomerate. As analogues to our own Solar System’s ‘Kuiper Belt’ or ‘Oort Cloud,’ the disks of debris left over from planet formation can be detected by astronomers and studied to help understand the processes that create planetary systems. Astronomers recently presented new observations of a nearby planetary system known as ‘61 Virginis’ (‘61 Vir’) and its debris disk. 61 Vir is a 4.6-billion-year- old star, about the size of our Sun, which is located approximately 28 light-years away. At least three planets orbit the parent star, which are five, 18, and 23 times more massive than the Earth. One of the most intriguing features of this system is its debris disk, which extends from 30 to at least 100 astronomical units (‘au,’ the average distance from the Sun to the Earth) from the star. A team of astronomers led by Sebastian Marino of the University of Cambridge (UK) has performed observations of 61 Vir’s debris disk using the Atacama Large Millimetre/submillimetre Array (ALMA) in Chile.
    [Show full text]