Surprise! When a brown dwarf is actually a planetary mass object

Sometimes a brown dwarf is actually a planet—or planet-like anyway. A team led by Carnegie’s Jonathan Gagné, and including researchers from the Institute for Research on Exoplanets (iREx) at Université de Montréal, University of California San Diego and the American Museum of Natural History, discovered that what astronomers had previously thought was one of the closest brown dwarfs to our own Sun is in fact a planetary mass object.

Their results are published by The Astrophysical Journal Letters.

An artist’s conception of SIMP J013656.5+093347, or SIMP0136 for short, which the research team determined is a planetary like member of a 200-million-year-old group of stars called Carina-Near. Image courtesy of NASA/JPL, slightly modified by J. Gagné.

Smaller than stars, but bigger than giant planets, brown dwarfs are too small to sustain the hydrogen fusion process that fuels stars and allows them to remain hot and bright for a long time. So after formation, brown dwarfs slowly cool down and contract over time. The contraction usually ends after a few hundred million years, although the cooling is continuous.

“This means that the temperatures of brown dwarfs can range from as hot as stars to as cool as planets, depending on how old they are,” said the AMNH’s Jackie Faherty, a co-author on this discovery.

The team determined that a well-studied object known as SIMP J013656.5+093347, or SIMP0136 for short, is a planetary like member of a 200-million-year-old group of stars called Carina-Near.

Groups of similarly aged stars moving together through space are considered prime locations to search for free-floating planetary like objects, because they provide the only means of age-dating these cold and isolated worlds. Knowing the age, as well as the temperature, of a free-floating object like this is necessary to determine its mass.

Gagné and the research team were able to demonstrate that at about 13 times the mass of Jupiter, SIMP0136 is right at the boundary that separates objects that are called brown dwarfs, which have a short-lived burning of deuterium right after they form, from those that are called planets, which don’t do fusion at any time.

Free-floating planetary mass objects are valuable because they are very similar to gas giant exoplanets that orbit around stars, like our own Solar System’s Jupiter or Saturn, but it is comparatively much easier to study their atmospheres. Observing the atmospheres of exoplanets found within distant star systems is challenging, because dim light emitted by those orbiting exoplanets is overwhelmed by the brightness of their host stars, which blinds the instruments that astronomers use to characterize an exoplanet’s atmospheres.

“The implication that the well-known SIMP0136 is actually more planet-like than we previously thought will help us to better understand the atmospheres of giant planets and how they evolve,” Gagné said.

They may be easier to study in great detail, but these free-floating worlds are still extremely hard to discover unless scientists spend a lot of time observing them at the telescope, because they can be located anywhere in the sky and they are very hard to tell apart from brown dwarfs or very small stars. For this reason, researchers have confirmed only a handful of free-floating planetary like objects so far.

Étienne Artigau, co-author and leader of the original SIMP0136 discovery, added: “This newest addition to the very select club of free-floating planetary like objects is particularly remarkable, because we had already detected fast-evolving weather patterns on the surface of SIMP0136, back when we thought it was a brown dwarf.”

In a field where analyzing exoplanet atmospheres is of the utmost interest, having already seen evidence of weather patterns on an easier-to-observe free-floating object that exists away from the brightness of its host star is an exciting realization.

 

More information

The article SIMP J013656.5+093347 is likely a Planetary-mass Object in the Carina-Near Moving Group is published in The Astrophysical Journal Letters. In addition to Jonathan Gagné (Carnegie Institution of Washington) and Jackie Faherty (AMNH) and Étienne Artigau (Institute for research on exoplanets at Université de Montréal), the team includes Adam Burgasser and Daniella Bardalez Gagliuffi (University of California San Diego), as well as Sandie Bouchard, Loïc AlbertLison MaloDavid LafrenièreRené Doyon (iREx at UdeM).

This work was supported by grants from the National Science and Engineering Research Council of Canada and by a NASA Sagan fellowship.

The Carnegie Institution for Science 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.

Contact
Jonathan Gagné
jgagne@carnegiescience.edu

Source
Natasha Metzler/Jonathan Gagné
Carnegie Institution for Science
nmetzler@carnegiescience.edu, jgagne@carnegiescience.edu

Marie-Eve Naud
Institute for research on exoplanets, Université de Montréal
514-343-6111, x 7077
irex@astro.umontreal.ca

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