Superfast changes to the intensity of a jet blasting out from a small black hole have been detected for the first time
Astronomers have spotted mysterious changes in a jet of highly
magnetic plasma blasted out by a small black hole that is gorging on gas and
dust.
The feature takes the form of periodic changes in the jet occurring within
a fraction of a second that have been detected by the Five-hundred-meter
Aperture Spherical radio Telescope (FAST) in China.
Astronomers know that the strange blinking object, called GRS
1915+105, consists of a regular star orbiting
a stellar black hole, a black hole that was born
after a massive star had died. As the star orbits the black hole, some of its
material gets sucked into the cosmic monster, which fails to swallow
all of the material and instead accelerates some of it into the jet that appears
to squirt from its poles.
The team behind the observation thinks that the measured changes
in the jet's energy could be due to the fact that the black hole's rotation isn't aligned with its accretion disk, the disk of orbiting matter it is
feasting on. That could be causing the jet to wobble almost
like a cosmic spinning top. When the jet points away, its energy drops. A
fraction of a second later, it returns to normal when the system rotates back.
"The peculiar signal has a rough period of 0.2 seconds, or a
frequency of about 5 Hertz," Wei Wang, a professor of astrophysics at
Wuhan University in China and the lead author of the research, said in a statement. "Such a signal does not always exist and only shows up
under special physical conditions. Our team was lucky enough to catch the
signal twice — in January 2021 and June 2022,
respectively."
GRS 1915+105 is what researchers call a micro
quasar, a star-scale version of a quasar. Quasars are extremely bright
galactic hearts that harbor supermassive black holes that are millions or even
billions of times more massive than the sun.
These cosmic titans draw in surrounding matter with the force of
their enormous gravity. Some of this matter falls
past the black hole's event horizon, the point of no return from beyond which
not even light can escape. Some material, however, escapes this fate and
instead gets channeled toward the black hole's poles, emanating into space in
the form of the super-energetic jets. This is also happening in micro
quasars, albeit on a much smaller scale.
Officially called quasi-periodic oscillations (QPO), changes seen
in GRS 1915+105, have never been seen in radio waves from such a black hole
before. QPOs are useful for understanding the physics of black holes and their
surrounding systems, so this observation of this changing micro
quasar, located around 28,000 light-years from
Earth in the direction of the constellation Aquila, could shed light on the
feeding habits of smaller black holes.
This QPO, seen in radio waves, could be the first evidence of
changes in jets of this type, but what exactly is causing these oscillations remains a
mystery.
"In accreting black hole systems, X-rays usually probe the accretion disk around the black hole while radio emission usually probes the jet launched from the disk and the black hole," Bing Zhang, an astronomer at the University of Nevada and co-author of the researcher, said in the statement. "The detailed mechanism to induce temporal modulation in a relativistic jet is not identified, but one plausible mechanism would be that the jet is underlying precession, which means the jet direction is regularly pointing towards different directions and
returns to the original direction once every about 0.2 seconds."
This effect may be caused by a misalignment between the spin axis
of the black hole and the disk of hot and bright gas and dust around it. This
would arise as a result of the fact that as the stellar mass black hole spins, it drags the very
fabric of spacetime around with it — an effect called the Lense–Thirring of just
frame-dragging.
"Other possibilities exist, though, and continued
observations of this and other galactic micro quasars will
bring more clues to understand these mysterious QPO signals," said Zhang.
The team’s research was published in the July 26 edition of the journal Nature
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