An international team of researchers has detected an incredible astronomical object: a pulsar that spins over 42,000 times every minute. This is the second-fastest-spinning pulsar ever discovered.
The findings, reported in the Astrophysical Journal Letters, describe PSR J0952–0607, the leftover core of a star that became a supernova. It's a type of neutron star so it has a significant mass, about 1.4 times the mass of the Sun, in a tiny volume. It wouldn’t be much larger than Manhattan.
But unlike many neutron stars, PSR J0952–0607 is a pulsar. A beam of radiation is emitted by these objects and as they spin, they appear to pulsate, hence the name. This pulsar rotates 707 times each second.
The discovery was possible by combining the data from NASA’s Fermi Gamma-ray Space Telescope with the Netherlands-based Low-Frequency Array (LOFAR) radio telescope. It was detected at a frequency much lower than conventional radio searches, which might suggest that there’s a whole new population of ultra-fast pulsars waiting to be found.
“Roughly a third of the gamma-ray sources found by Fermi have not been detected at other wavelengths,” Elizabeth Ferrara, a member of the discovery team at NASA's Goddard Space Center, stated. “Many of these unassociated sources may be pulsars, but we often need follow-up from radio observatories to detect the pulses and prove it. There's a real synergy across the extreme ends of the electromagnetic spectrum in hunting for them.”
This pulsar also has another label. It’s a black widow pulsar, nicknamed because the stellar object is consuming a companion star. The team identified J0952’s companion, a star that has been eroded so dramatically that it only weighs about 20 times the mass of Jupiter.
The fastest-spinning pulsar rotates on itself about 43,000 times every minute, but even that incredible value is nowhere close to the theoretical limit scientists estimated. A pulsar could spin as fast as 72,000 times per minute before it would be ripped apart. So where are these extremely fast pulsars?
“There is growing evidence that the fastest-spinning pulsars tend to have the steepest spectra,” said co-author Ziggy Pleunis, from McGill University in Montreal. “Since LOFAR searches are more sensitive to these steep-spectrum radio pulsars, we may find that even faster pulsars do, in fact, exist and have been missed by surveys at higher frequencies.”