Astronomers have detected what may be the most rapidly rotating brown dwarf ever measured.
The data collected so far from this star show that it could be rotating every 17, 34, or 51 minutes—an ambiguity that requires the collection of more data to identify which of the three measurements is this star’s rotational period. But, scientists report, even the longest of these rotation periods would mean this brown dwarf rotates much faster than any measured so far.
The super-fast rotation period was measured by using the 305-meter Arecibo radio telescope—the same telescope that was used to discover the first planets ever found outside our solar system.
“Our new detection of an ultra-cool dwarf emphasizes Arecibo’s amazing sensitivity, which enables measurements of the magnetic fields of very-low-mass stars, brown dwarfs, and potentially planets,” says Alex Wolszczan, a professor of astronomy and astrophysics at Penn State University.
“Because planetary magnetic fields protect life from the harmful effects of stellar activity, it is clear that future programs of this kind using the Arecibo telescope will be crucial to our understanding of the habitability of planets around other stars.”
The radio flares the star emits allowed them to measure the rotation. The results show that radio observations can help discover and study even the coolest brown dwarfs, and possibly young giant planets.
The discovery is detailed in a recent issue of the Astrophysical Journal Letters.
Missing link between planets and stars
“Our discovery of the super-fast rotation of J1122+25 poses new challenges for the theoretical models of the rotational evolution of these objects and the internal dynamos that power their magnetic fields,” says Matthew Route, a Senior Scientific Applications Analyst at Purdue University who was involved with the work.
J1122+25 is the short version of the scientific name of this new brown dwarf, WISEPC J112254.73+255021.5.
“The radio flaring and rapid rotation of J1122+25 can reveal a lot about the origin and evolution of the magnetic fields of brown dwarfs, and how this knowledge can be applied to young giant planets,” Route says.
Brown dwarfs like J1122+25 are sometimes called “failed stars” because they did not accumulate enough material when they formed in order to fuse hydrogen into helium, the process that enables stars to shine. The lack of continuous energy production from fusion makes brown dwarfs much colder and dimmer than most stars and gives them much different chemistry.
For some of them, internal structure in connection with rapid rotation can generate strong magnetic fields and the dramatic radio flares that have been detected by the Arecibo telescope.
Many astronomers treat brown dwarfs as the “missing link” between stars and planets. Brown dwarfs share many physical traits with gas-giant planets like Jupiter. Studies of ultra-cool brown dwarfs like J1122+25 can be used to infer the properties of giant planets, which are much harder than stars to study in detail. J1122+25 is about one-sixth the temperature of the Sun, and emits light primarily in infrared wavelengths.
Source: Penn State
