The star’s extraordinary magnetic field is potentially associated with a constant flurry of solar flare-like eruptions. As with our Sun, these flares would trace tightly wound magnetic field lines that act like cosmic particle accelerators, warping the path of electrons and causing them to emit telltale radio signals that can be detected with ALMA.
Such intense flare activity, the astronomers note, would barrage nearby planets with charged particles.
“If we lived around a star like this one, we wouldn’t have any satellite communications. In fact, it might be extremely difficult for life to evolve at all in such a stormy environment,” said Peter Williams of the Harvard-Smithsonian Center for Astrophysics (CfA) in Cambridge, Massachusetts.
The team used ALMA to study the well-known red dwarf star TVLM 513-46546, which is located about 35 light-years from Earth in the constellation Boötes.
The star is a mere 10 percent the mass of the Sun and is so small and cool that it’s right on the dividing line between stars (which fuse hydrogen) and brown dwarfs (which don’t). One of the things that make this small star remarkable is that it spins rapidly, completing a full rotation about every two hours. Our Sun takes about 25 days to rotate once at its equator.
Previous data from the National Radio Astronomy Observatory’s Karl G. Jansky Very Large Array in Socorro, New Mexico, show that this star exhibits a magnetic field that rivals the Sun’s most extreme magnetic regions and is several hundred times stronger than the Sun’s average magnetic field.
This puzzled astronomers because the physical processes that generate the Sun’s magnetic field shouldn’t operate in such a small star.
“This star is a very different beast from our Sun, magnetically speaking,” said Edo Berger from CfA.
When the researchers examined the star with ALMA, they detected emission at a particularly high frequency — 95 GHz or a wavelength of about 3 millimeters. Such a radio signal is produced by a process known as synchrotron emission in which electrons zip around powerful magnetic field lines — the more powerful the magnetic field, the higher the frequency.
This is the first time that flare-like emission at such high frequencies has been detected from a red dwarf star. It is also the first time that such a star has been detected at millimeter wavelengths, opening up a new avenue of study with ALMA.
Our Sun generates similar emission from solar flares but only intermittently. What’s more, the emission from this star is 10,000 times brighter than what our Sun produces, even though it has less than one-tenth of the Sun’s mass. The fact that ALMA detected this emission in a brief 4-hour observation suggests that the red dwarf is continuously active.
This has important implications for the search for habitable planets outside the solar system. Red dwarfs are the most common type of star in our galaxy, which makes them promising targets for planet searches. But because a red dwarf is so cool, a planet would have to orbit close to the star to be warm enough for liquid water to exist at its surface. That proximity would put the planet right in the bull’s-eye for radiation that could strip its atmosphere or destroy any complex molecules on its surface.
Astronomers will study similar stars in the future to determine whether this one is an oddball or an example of an entire class of stormy stars.