Exoplanets & Exomoons

Rocky Planet Found in Habitable Zone of Proxima Centauri

By Keith Cowing
Press Release
Carnegie Institution for Science
August 24, 2016
Filed under
Rocky Planet Found in Habitable Zone of Proxima Centauri
Rocky planet orbiting Proxima Centauri
ESO

An international team of astronomers including Carnegie’s Paul Butler has found clear evidence of a planet orbiting Proxima Centauri, the closest star to our solar system.

The new world, designated Proxima b, orbits its cool red parent star every 11 days and has a temperature suitable for liquid water to exist on its surface, if it were present. This rocky world is a little more massive than the Earth and is the closest exoplanet to us; it may even be the closest possible abode for life beyond our own Sun. A paper describing this milestone finding is published by Nature.

Just over four light-years from our solar system sits a red dwarf star named Proxima Centauri. This cool star in the constellation of Centaurus is too faint to be seen with the naked eye and is close to the much brighter pair of stars known as Alpha Centauri A and B.

During the first half of 2016, the HARPS spectrograph on the European Southern Observatory’s 3.6-meter telescope at La Silla regularly observed Proxima Centauri, as did other professional and amateur telescopes around the world. The team of astronomers, called the Pale Red Dot campaign, led by Carnegie alum Guillem Anglada-EscudĂ© of Queen Mary, University of London was looking for a tiny back-and-forth wobble in the star caused by the gravitational pull of an orbiting planet.

In addition to data gathered by the Pale Red Dot campaign, the paper incorporates contributions from scientists who have been observing Proxima Centauri for years, including Butler.

As this was a topic with very wide public interest, the progress of the campaign between mid-January and April 2016 was shared publicly as it occurred on the Pale Red Dot website and via social media. Numerous outreach articles from specialists all around the world accompanied the reports on data collection.

Anglada-EscudĂ© explains the background to this unique search: “The first hints of a possible planet were spotted back in 2013, but the detection was not convincing. Since then we have worked hard to get further observations off the ground with help from ESO and others. The recent Pale Red Dot campaign has been about two years in the planning.”

The Pale Red Dot data, when combined with earlier observations, revealed a truly exciting result. At regular intervals, Proxima Centauri is approaching Earth at about 5 kilometers per hour — normal human walking pace — and at opposite times in those cycles it is receding at the same speed. This regular pattern repeats with a period of 11.2 days. Careful analysis of how tiny the resulting Doppler shifts were showed that they indicated the presence of a planet with a mass at least 1.3 times that of the Earth, orbiting about 7 million kilometers from Proxima Centauri — only 5 percent of the distance between the Earth and the Sun.

One complication to the analysis is that red dwarfs like Proxima Centauri are active stars, and their natural brightness variations could mimic the presence of a planet. In order to exclude this possibility, the team also monitored the changing brightness of the star very carefully during the campaign using the ASH2 telescope at the San Pedro de Atacama Celestial Explorations Observatory in Chile and the Las Cumbres Observatory Global Telescope Network.

Although the planet companion, Proxima b, orbits much closer to its star than Mercury does to the Sun in our solar system, the star itself is far fainter and cooler than the Sun. As a result, Proxima b has an estimated temperature that — if water were present — would allow it in a liquid state on its surface, thus placing it within the so-called “habitable zone” around the star.

Despite the temperate orbit of Proxima b, the conditions on the surface may be strongly affected by the ultraviolet and x-ray flares from the star — far more intense than the Earth experiences from the Sun.

“The discovery of the potentially habitable planet around Proxima Cen is the culmination of 30 years of work that has improved stellar velocity measurement precision from 300 m/s to 1 m/s,” Butler said. “This work has resulted in the discovery of hundreds of planets around the nearest stars, and now a potentially habitable planet around the nearest star in the sky. This work confirms the Kepler satellite and precision velocity studies that have shown that potentially habitable planets are common, and points the way to the future when such planets will be directly observed with giant ground- and space-based telescopes.”

Image (available from Natasha Metzler):
This artist’s impression shows a view of the surface of the planet Proxima b orbiting the red dwarf star Proxima Centauri, the closest star to the solar system. The double star Alpha Centauri AB also appears in the image to the upper-right of Proxima itself. Proxima b is a little more massive than the Earth and orbits in the habitable zone around Proxima Centauri, where the temperature is suitable for liquid water to exist on its surface. Photo is courtesy of ESO/M. Kornmesser.

Image (available from Natasha Metzler):
An angular size comparison of how Proxima will appear in the sky seen from Proxima b, compared to how the Sun appears in our sky on Earth. Proxima is much smaller than the Sun, but Proxima b lies very close to its star. Image is courtesy of ESO/G. Coleman.

Reference:
“A Terrestrial Planet Candidate in a Temperate Orbit Around Proxima Centauri,” G. Anglada-EscudĂ© et al., 2016 August 25, Nature [preprint (PDF): http://www.eso.org/public/archives/releases/sciencepapers/eso1629/eso1629a.pdf].

The team is composed of Guillem Anglada-EscudĂ© (Queen Mary, University of London, London, UK), Pedro J. Amado (Instituto de AstrofĂ­sica de AndalucĂ­a — CSIC, Granada, Spain), John Barnes (Open University, Milton Keynes, UK), Zaira M. Berdiñas (Instituto de AstrofĂ­sica de Andalucia — CSIC, Granada, Spain), R. Paul Butler (Carnegie Institution of Washington, Department of Terrestrial Magnetism, Washington, USA), Gavin A. L. Coleman (Queen Mary, University of London, London, UK), Ignacio de la Cueva (Astroimagen, Ibiza, Spain), Stefan Dreizler (Institut fĂĽr Astrophysik, Georg-August-Universität Göttingen, Göttingen, Germany), Michael Endl (The University of Texas at Austin and McDonald Observatory, Austin, Texas, USA), Benjamin Giesers (Institut fĂĽr Astrophysik, Georg-August-Universität Göttingen, Göttingen, Germany), Sandra V. Jeffers (Institut fĂĽr Astrophysik, Georg-August-Universität Göttingen, Göttingen, Germany), James S. Jenkins (Universidad de Chile, Santiago, Chile), Hugh R. A. Jones (University of Hertfordshire, Hatfield, UK), Marcin Kiraga (Warsaw University Observatory, Warsaw, Poland), Martin KĂĽrster (Max-Planck-Institut fĂĽr Astronomie, Heidelberg, Germany), MarĂ­a J. LĂłpez-González (Instituto de AstrofĂ­sica de AndalucĂ­a — CSIC, Granada, Spain), Christopher J. Marvin (Institut fĂĽr Astrophysik, Georg-August-Universität Göttingen, Göttingen, Germany), Nicolás Morales (Instituto de AstrofĂ­sica de AndalucĂ­a — CSIC, Granada, Spain), Julien Morin (Laboratoire Univers et Particules de Montpellier, Universit de Montpellier, Montpellier, France), Richard P. Nelson (Queen Mary, University of London, London, UK), JosĂ© L. Ortiz (Instituto de AstrofĂ­sica de AndalucĂ­a — CSIC, Granada, Spain), Aviv Ofir (Weizmann Institute of Science, Rehovot, Israel), Sijme-Jan Paardekooper (Queen Mary, University of London, London, UK), Ansgar Reiners (Institut fĂĽr Astrophysik, Georg-August-Universität Göttingen, Göttingen, Germany), Eloy Rodriguez (Instituto de AstrofĂ­sica de AndalucĂ­a — CSIC, Granada, Spain), Cristina Rodriguez-Lopez (Instituto de AstrofĂ­sica de AndalucĂ­a — CSIC, Granada, Spain), Luis F. Sarmiento (Institut fĂĽr Astrophysik, Georg-August-Universität Göttingen, Göttingen, Germany), John P. Str
achan (Queen Mary, University of London, London, UK), Yiannis Tsapras (Astronomisches Rechen-Institut, Heidelberg, Germany), Mikko Tuomi (University of Hertfordshire, Hatfield, UK) and Mathias Zechmeister (Institut für Astrophysik, Georg-August-Universität Göttingen, Göttingen, Germany).

The authors acknowledge support from: Leverhulme Trust/UK RPG-2014-281 (HRAJ, GAE, MT), MINECO/Spain AYA-2014- 54348-C3-1-R (PJA, CRL, ZMB, ER),MINECO/Spain ESP2014-54362-P (MJLG),MINECO/Spain AYA-2014-56637-C2-1-P(JLO, NM), J.A./Spain 2012-FQM1776 (JLO, NM), CATA-Basal/Chile PB06 Conicyt (JSJ), Fondecyt/Chile project #1161218 (JSJ), STFC/UK ST/M001008/1 (RPN, GALC, GAE), STFC/UK ST/L000776/1 (JB), ERC/EU Starting Grant #279347 (AR, LS, SVJ), DFG/Germany Research Grants RE 1664/9-2(AR), RE 1664/12-1(MZ), DFG/Germany Collaborative Research Center 963(CJM, SD), DFG/Germany Research Training Group 1351(LS), and NSF/USA grant AST-1313075 (ME).

This work was based on observations made with ESO Telescopes at the La Silla Paranal Observatory under programmes 096.C-0082 and 191.C-0505. Observations were obtained with ASH2, which is supported by the Instituto de AstrofĂ­sica de AndalucĂ­a and Astroimagen company. This work makes use of observations from the LCOGT network. The authors acknowledge the effort of the UVES/M-dwarf and the HARPS/Geneva teams, which obtained a substantial amount of the data used in this work.

The Carnegie Institution for Science (http://carnegiescience.edu) is a private, nonprofit organization headquartered in Washington, D.C., with six research departments throughout the U.S. Since its founding in 1902, the Carnegie Institution has been a pioneering force in basic scientific research. Carnegie scientists are leaders in plant biology, developmental biology, astronomy, materials science, global ecology, and Earth and planetary science.

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