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EI2GYB > ASTRO 28.10.25 19:02z 140 Lines 7898 Bytes #126 (0) @ WW
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Subj: Scientists hear 2 newborn black holes 'crying' through ripp
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Scientists hear 2 newborn black holes 'crying' through ripples in spacetime -
and one had a birth unlike anything seen before
"GW241011 and GW241110 are among the most novel events among the several
hundred that the LIGO-Virgo-KAGRA network has observed."
Scientists have "heard" the symphony of two newborn black holes - each created
when its respective parent black holes crashed together and merged. One of
those collision events, in fact, was the first of its kind.
The detection of the baby black holes and information about the four parent
black holes that forged them came courtesy of ripples in spacetime, or
gravitational waves, caused by the violent cosmic events that gave birth to
them. Those waves were registered by the LIGO (Laser Interferometer
Gravitational-Wave Observatory), Virgo, and KAGRA (Kamioka Gravitational Wave
Detector) gravitational wave detectors.
The LIGO-Virgo-KAGRA collaboration detected the first merger, designated
GW241011, on Oct. 11, 2024. It was the result of a black hole with around 17
times the mass of the sun crashing into its partner black hole with a mass
around seven times that of our star. The event was calculated to have happened
around 700 million light-years from Earth. Decoding the resultant gravitational
wave signal revealed a couple of things: The masses of the black holes involved
as well as the fact that the larger of the pair is one of the most rapidly
spinning black holes ever observed.
Less than one month after this groundbreaking detection, on Nov. 11, 2024, the
gravitational wave instruments "heard" another newborn black hole screaming
after the violent collision of its progenitors. This signal, GW241110,
originated from a collision between black holes with 16 and eight times the
mass of the sun and occurred about 2.4 billion light-years away. This signal
revealed that one of the black holes involved was spinning in the opposite
direction of its orbit around the other black hole, the first time such a
characteristic has been seen for merging binary black holes.
"Each new detection provides important insights about the universe, reminding
us that each observed merger is both an astrophysical discovery but also an
invaluable laboratory for probing the fundamental laws of physics," Carl-Johan
Haster, an assistant professor of astrophysics at the University of Nevada, Las
Vegas (UNLV), said in a statement. "Binaries like these had been predicted
given earlier observations, but this is the first direct evidence for their
existence."
Both events indicate the existence of so-called second-generation black holes.
"GW241011 and GW241110 are among the most novel events among the several
hundred that the LIGO-Virgo-KAGRA network has observed," Stephen Fairhurst,
LIGO Collaboration spokesperson and a Cardiff University professor, said in the
statement. "With both events having one black hole that is both significantly
more massive than the other and rapidly spinning, they provide tantalizing
evidence that these black holes were formed from previous black hole mergers."
Black holes: the second generation
The idea that the detected black holes are second-generation comes from the
difference in size between the larger black holes and their smaller companions
in the two mergers. The more diminutive black holes appear to have been almost
half the mass of their companions. The orbit-opposing orientation of the larger
black hole's spin in the merger that produced the signal GW241110 is also
evidence of a prior merger having produced that dominant black hole.
The process of black hole growth by collision after collision is known as
"hierarchical merger." This is believed to occur in densely populated regions
like star clusters, where black holes are more likely to meet and coalesce over
and over again, resulting in subsequently larger black holes.
GW241011 offers scientists the opportunity to probe the limits of Albert
Einstein's 1915 theory of gravity, general relativity, from which the concept
black holes and gravitational waves both emerged.
For instance, the rapid rotation of the black hole involved in this particular
merger deforms the object, and that leaves a unique impression in the
gravitational waves it emits. This means that this event can be compared to
general relativity and the predictions physicist Roy Kerr made using Einstein's
theory concerning rotating black holes. The black holes of GW241011 conformed
to Kerr's solution to general relativity, the study team explains, helping
verify it as well as Einstein's magnum opus theory itself in extreme
circumstances. This includes confirming for the third time within a
gravitational wave signal (GW241011) the "hum" of a higher harmonic, akin to
the overtones of musical instruments.
The LIGO-Virgo-KAGRA collaboration also thinks these gravitational wave signals
could be key to unlocking something predicted but never before seen - something
outside the limits of general relativity.
Plus, the two black hole mergers behind these signals have the potential to
reveal more about an unrelated scientific field: particle physics.
Scientists can use rapidly rotating black holes to test the hypothesized
existence of ultralight bosons, or particles that exist beyond the Standard
Model of particle physics. Should they exist, ultralight bosons should draw the
rotational energy from spinning black holes. How much energy these particles
extract and how much they slow black holes down is dependent on their mass.
The revelation that the progenitor black hole of the merger behind GW241011 is
still rotating at a rapid rate after millions (or even billions) of years since
the merger that created it seems to rule out a range of ultralight boson masses.
"The detection and inspection of these two events demonstrate how important it
is to operate our detectors in synergy and to strive to improve their
sensitivities," Francesco Pannarale, co-chair of the Observational Science
Division of the LIGO-Virgo-KAGRA Collaborations and professor at Sapienza
University of Rome, said. "The LIGO and Virgo instruments taught us yet some
more about how black hole binaries can form in our universe, as well as about
the fundamental physics that regulates them at the very essence.
"By upgrading our instruments, we will be able to dive deeper into these and
other aspects with the increased precision of our measurements."
The team's research was published on Tuesday (Oct. 28) in the Astrophysical
Journal Letters.
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