An international research team led by Gregory Desvignes from the Max Planck Institute for Radio Astronomy in Bonn, Germany, has used the Effelsberg and Jodrell Bank radio telescopes to observe the precessing magnetar XTE J1810-197—a highly magnetized and ultra-dense neutron star—shortly after its X-ray enhanced activity and radio reactivation.
This precession damped on a timescale of a few months challenging some models used to explain the origin of the mysterious repeating fast radio bursts.
Magnetars are neutron stars with extreme and twisted magnetic fields, remnants after the collapse of fuel-exhausted massive stars. These objects are so dense that they contain 1 to 2 times the mass of the sun in a near-perfect sphere of about 12 km in radius.
Of the 30 known magnetars, only a handful have occasionally emitted radio waves, with their radio beam sweeping the sky like a lighthouse. Magnetars are widely considered to be the source for the Fast Radio Bursts (FRBs) with some models invoking freely precessing magnetars as responsible for the repeating FRBs.
Together with colleagues from the Jodrell Bank Center for Astrophysics and the Kavli Institute for Astronomy & Astrophysics, researchers from the Max Planck Institute for Radio Astronomy (MPIfR) are regularly inspecting some of these magnetars and unexpectedly caught one of them, XTE J1810-197, which started to emit radio emission in December 2018, shortly after the start of enhanced X-ray emission, and after a period of about 10 years during which it was radio quiet.
Embarking on an intense observing campaign following this event, the researchers noticed some very systematic changes in the properties of the radio light, namely its polarization, revealing a shift in the orientation of the magnetar’s radio beam with respect to Earth. The researchers attributed this to free precession, an effect that arises from a slight asymmetry in the magnetar’s structure, causing it to wobble around like a spinning top.
To their surprise, the free precession damped rapidly over the next few months and disappeared eventually. The disappearance of the precession with time contradicts the suggestion by many astronomers who believe that FRBs, that repeat with time, can be explained by precessing magnetars.
“We expected to see some variations in the polarization of this magnetar’s emission, as we knew this from other magnetars,” says Gregory Desvignes from the MPIfR, leading author of the study published in Nature Astronomy. “But we did not expect that these variations are so systematic, following exactly the behavior that would be caused by the wobbling of the star.”
Patrick Weltevrede from The University of Manchester adds, “Our findings were only made possible thanks to many years of dedicated monitoring of this magnetar with radio telescopes in Jodrell Bank and Effelsberg. We had to wait for over a decade before it started to produce radio emission, but when it did, it certainly didn’t disappoint.”
“Damped precession of magnetars might shed light on the inner structure of neutron stars, which is ultimately related to our fundamental understanding of matters,” says Lijing Shao from Peking University.
“Radio astronomy is truly fascinating. The enigma surrounding the origins of FRBs still persists. However, catching intriguing objects like magnetars in the act to learn more about FRBs, underscores the capabilities of our facilities,” concludes Michael Kramer, director at MPIfR and Head of it’s Fundamental Physics in Radio Astronomy Research Division.
Reference: Gregory Desvignes et al, A freely precessing magnetar following an X-ray outburst, Nature Astronomy (2024). DOI: 10.1038/s41550-024-02226-7