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 1. nature
 2. news
 3. article

  * NEWS
  * 24 May 2023

Gravitational-wave detector LIGO is back -- and can now spot more
colliding black holes than ever

The twin gravitational-wave detectors have started a new observation
run after a major upgrade.

  * Davide Castelvecchi

 1. Davide Castelvecchi
    View author publications

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The collision of two black holes holes is seen in this still from a
computer simulation.

LIGO can detect gravitational waves that are generated when two black
holes collide. Credit: The SXS Project

You have full access to this article via your institution.

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After a three-year hiatus made longer by pandemic troubles, the
search for gravitational waves -- ripples in space-time that are the
hallmarks of colliding black holes and other cosmic cataclysms -- has
resumed.

The Laser Interferometer Gravitational-Wave Observatory (LIGO), which
has two massive detectors in Hanford, Washington, and Livingston,
Louisiana, is now restarting with improved sensitivity after a
multimillion-dollar upgrade. The improvements should allow the
facility to pick up signals from colliding black holes every two to
three days, compared with once a week or so during its previous run
in 2019-20.

[d41586-023]

Gravitational-wave observatory LIGO set to double its detecting power

The Virgo detector near Pisa, Italy, which has undergone its own
EUR8.4-million (US$9-million) upgrade, was meant to join in, but
technical issues are forcing its team to extend its shutdown and
perform further maintenance. "Our expectation is we'll be able to
restart by the end of summer or early autumn," says Virgo
spokesperson Gianluca Gemme, a physicist at Italy's National
Institute for Nuclear Physics in Genoa.

KAGRA, a gravitational-wave detector located under Mount Ikenoyama,
Japan, is also restarting on 24 May. Its technology, although more
advanced -- it was inaugurated in 2020 -- is being fine-tuned, and its
sensitivity is still lower than LIGO's was in 2015. Principal
investigator Takaaki Kajita, a Nobel Prize-winning physicist at the
University of Tokyo, says that KAGRA will join LIGO's run for a month
and then shut down again for another period of commissioning. At that
point, the team will cool the interferometer's four main mirrors to
20 kelvin, Kajita says -- a feature that sets KAGRA apart from the
other detectors that will serve as the model for next-generation
observatories.

Black-hole mergers

Gravitational waves are produced by large, accelerating masses, and
the waves cyclically stretch and compress the fabric of space as they
travel. Starting with LIGO's historic first detection in 2015, most
of the 90 or so gravitational-wave events recorded so far have been
from the spiralling motion of pairs of black holes in the process of
merging into one; a handful have been produced similarly by the
merger of two neutron stars or a neutron star and a black hole.

LIGO, Virgo and KAGRA are all based on the same interferometer
concept, which involves splitting a laser beam into two and bouncing
the resulting beams between two mirrors at either end of a long
vacuum pipe. (At LIGO, the two 'arms' of the interferometer are each
4 kilometres long; at Virgo and KAGRA, they are 3 km.) The two beams
then come back and are made to overlap at a sensor in the middle. In
the absence of any disturbances to space-time, the beams'
oscillations cancel one another out. But the passage of gravitational
waves causes the arms to change in length with respect to each other,
so that the waves don't overlap perfectly, and the sensor detects a
signal.

Aerial view of the Laser Interferometer Gravitational-wave
Observatory in Livingston, Louisiana.

The LIGO detector in Livingston, Louisiana, is one of a pair based in
the United States.Credit: Xinhua/Caltech/MIT/LIGO Lab

Typical gravitational-wave events change the length of the arms by
only a fraction of the width of a proton. Sensing such minute changes
requires painstaking isolation from noise coming from the environment
and from the lasers themselves.

In upgrades carried out before the 2019-20 run, LIGO and Virgo
tackled some of this noise with a technique called light squeezing.
This approach deals with inherent noise caused by the fact that light
is made of individual particles: when the beams arrive at the sensor,
each individual photon can arrive slightly too early or too late,
which means that the laser waves don't overlap and cancel out
perfectly even in the absence of gravitational waves.

"It's like dropping a bucket of BBs [lead pellets]: it's going to
make a loud hiss, but they all hit randomly," physicist Lee McCuller
explained while showing a prototype of the LIGO interferometers at
the Massachusetts Institute of Technology (MIT) in Cambridge. Light
squeezing injects an auxiliary laser beam into the interferometer
that reduces that effect. "Its photons arrive more regularly, with
less noise," said McCuller, who is now at the California Institute of
Technology in Pasadena.

Quantum complications

The implementation of light squeezing has helped LIGO and Virgo to
improve the detectors' sensitivities to higher-frequency
gravitational waves.

But because of the bizarre rules of quantum mechanics, reducing the
uncertainty in the arrival time of the photons increases random
fluctuations in the laser waves' intensity. This causes the lasers to
push on the interferometer mirrors and make them jitter, adding a
different type of noise and potentially reducing their sensitivity to
low-frequency gravitational waves. This is a "beautiful manifestation
of nature", says MIT experimentalist Nergis Mavalvala, who helped to
lead the development of the squeezing technology. "You cannot make an
infinitely precise measurement: you have to pay the price somewhere
else," she says.

[d41586-023]

What 50 gravitational-wave events reveal about the Universe

To deal with this issue, an important change in the most-recent
upgrades of both LIGO and Virgo has been to build extra
300-metre-long vacuum pipes with mirrors at the ends, to store the
auxiliary 'squeezing' beam for 2.5 milliseconds before injecting it
into the interferometer. The role of these pipes is to shift the
waves of the auxiliary laser by distinct amounts depending on their
wavelengths. This means that squeezing will be selective: it will
decrease the noise at high frequency while also reducing mirror
jitter at low frequencies.

MIT physicist Victoria Xu was part of the team that fine-tuned the
new squeezing system at LIGO's Hanford laboratory, and she recalls
the pleasant surprise when it was first turned on last November.
"Things worked almost exactly as you might expect," she says.

Collapsing stars

With the improved sensitivity of the detectors, researchers will be
able to extract more-detailed information about the spiralling
objects that produce gravitational waves, including how each spins
around its axis and how they revolve around each other. This means
putting Albert Einstein's general theory of relativity -- which
predicts the existence of both black holes and gravitational waves --
to stricter tests than ever before. The sheer number of observations
will improve the big picture of how, and how often, black holes form
from massive stars that collapse in on themselves.

Astrophysicists also anticipate that gravitational waves will reveal
distinct types of signal in addition to those from black-hole
mergers. One major hope is to pick up the gravitational signal of a
collapsing star before it manifests as a supernova explosion -- a feat
that will be possible only if the collapse occurs somewhere in the
Galaxy. Another ambition is to sense the continuous gravitational
waves produced by ruggedness in the surface of a pulsar, a spinning
neutron star that emits pulses of radiation.

The family of interferometers is due to expand by the end of the
decade. The Indian government has announced that it will fund
LIGO-India, a replica of the US observatories to be built in part
with LIGO's spare components.

doi: https://doi.org/10.1038/d41586-023-01732-4

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You have full access to this article via your institution.

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Related Articles

  * [d41586-023] Gravitational-wave observatory LIGO set to double
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