The relation between size and temperature at the point where stars end and brown dwarfs begin (based on a figure from the publication)
Image credit: P. Marenfeld & NOAO/AURA/NSF.
Stars come in a tremendous size range, from many tens of times bigger than the Sun to a tiny fraction of its size. But the answer to just how small an astronomical body can be, and still be a star, has never been known. What is known is that objects below this limit are unable to ignite and sustain hydrogen fusion in their cores: these objects are referred to as brown dwarfs.
In research accepted for publication in the Astronomical Journal, the RECONS (Research Consortium On Nearby Stars)
group from Georgia State University has found clear observational
evidence for the theoretically predicted break between very low mass
stars and brown dwarfs. The data came from the SOAR (Southern
Observatory for Astrophysical Research) 4.1-m telescope and the SMARTS
(Small and Moderate Aperture Research Telescope System) 0.9-m telescope
at the Cerro Tololo Inter-American Observatory (CTIO) in Chile.
For most of their lives, stars obey a relationship referred to as the
main sequence, a relation between luminosity and temperature – which is
also a relationship between luminosity and radius. Stars behave like
balloons in the sense that adding material to the star causes its radius
to increase: in a star the material is the element hydrogen, rather
than air which is added to a balloon. Brown dwarfs, on the other hand,
are described by different physical laws (referred to as electron
degeneracy pressure) than stars and have the opposite behavior. The
inner layers of a brown dwarf work much like a spring mattress: adding
additional weight on them causes them to shrink. Therefore brown dwarfs
actually decrease in size with increasing mass.
As Dr. Sergio Dieterich, the lead author, explained, “In order to
distinguish stars from brown dwarfs we measured the light from each
object thought to lie close to the stellar/brown dwarf boundary. We
also carefully measured the distances to each object. We could then
calculate their temperatures and radii using basic physical laws, and
found the location of the smallest objects we observed (see the
attached illustration, based on a figure in the publication). We see
that radius decreases with decreasing temperature, as expected for
stars, until we reach a temperature of about 2100K. There we see a gap
with no objects, and then the radius starts to increase with decreasing
temperature, as we expect for brown dwarfs. “
Dr. Todd Henry, another author, said: “We can now point to a
temperature (2100K), radius (8.7% that of our Sun), and luminosity
(1/8000 of the Sun) and say ‘the main sequence ends there’ and we can
identify a particular star (with the designation 2MASS J0513-1403) as a
representative of the smallest stars.”
Aside from answering a fundamental question in stellar astrophysics
about the cool end of the main sequence, the discovery has significant
implications in the search for life in the universe. Because brown
dwarfs cool on a time scale of only millions of years, planets around
brown dwarfs are poor candidates for habitability, whereas very low mass
stars provide constant warmth and a low ultraviolet radiation
environment for billions of years. Knowing the temperature where the
stars end and the brown dwarfs begin should help astronomers decide
which objects are candidates for hosting habitable planets.
Also, because brown dwarfs cool forever, they eventually become a
type of
macroscopic dark matter, so it is important to know how much dark matter
is trapped in the form of extremely old and cold brown dwarfs.
The research highlights the capabilities of the National Optical
Astronomy Observatory system in a single project. The SOAR observations
provided the missing link to a wealth of data that had previously been
obtained using telescopes under the auspices of NOAO. As Dieterich
explains: “We used the SOAR 4.1-m telescope to measure the visible light
of faint stars and brown dwarfs, and the CTIO 0.9-m telescope to obtain
precise measurements of their distances. We then combined these
measurements with infrared data taken at the CTIO 1.3-m telescope and
the WISE space telescope. Three out of four of these telescopes are
public telescopes located at CTIO, and the fourth explores wavelengths
that are only accessible from space.”
CTIO is a division of the National Optical Astronomy Observatory,
which is operated by the Association of Universities for Research in
Astronomy Inc. (AURA) under a cooperative agreement with the National
Science Foundation.
Science Contact
Dr. Sergio Dieterich
Astronomy Department
Georgia State University
Atlanta, GA
E-mail: dieterich@chara.gsu.edu
phone: +1 678-350-4741
Dr. Sergio Dieterich
Astronomy Department
Georgia State University
Atlanta, GA
E-mail: dieterich@chara.gsu.edu
phone: +1 678-350-4741
