Unusually Lightweight Black Hole Candidate Spotted by LIGO

The image shows the coalescence and merger of a lower mass-gap black hole (dark gray surface) with a neutron star (greatly tidally deformed by the black hole's gravity). This still image from a simulation of the merger highlights just the neutron star's lower density components, ranging from 60 grams per cubic centimeter (dark blue) to 600 kilograms per cubic centimeter (white). Its shape highlights the strong deformations of the low-density material of the neutron star Credit: Ivan Markin, Tim Dietrich (University of Potsdam), Harald Paul Pfeiffer, Alessandra Buonanno (Max Planck Institute for Gravitational Physics)

In May 2023, shortly after LIGO (Laser Interferometer Gravitational-wave Observatory) turned back on for its fourth run of observations, it detected a gravitational-wave signal from the collision of an object, most likely a neutron star, with a suspected black hole possessing a mass that is 2.5 to 4.5 times more than that of our Sun. This signal, called GW230529, is intriguing to researchers because the candidate black hole's mass falls within a so-called mass gap between the heaviest known neutron stars, which are slightly more than two solar masses, and the lightest known black holes, which are about five solar masses. While the gravitational-wave signal alone cannot reveal the true nature of this object, future detections of similar events, especially those accompanied by bursts of light, could hold the key to answering the question of how lightweight black holes can be.

"The latest finding demonstrates the impressive science capability of the gravitational-wave detector network, which is significantly more sensitive than it was in the third observing run," says Jenne Driggers (PhD '15), detection lead scientist at LIGO Hanford in Washington, one of two facilities, along with LIGO Livingston in Louisiana, that make up the LIGO Observatory.

LIGO made history in 2015 after carrying out the first direct detection of gravitational waves in space. Since then, LIGO and its partner detector in Europe, Virgo, have detected nearly 100 mergers between black holes, a handful between neutron stars, as well as mergers between neutron stars and black holes. The Japanese detector KAGRA joined the gravitational-wave network in 2019, and the team of scientists who collectively analyze data from all three detectors is known as the LIGO–Virgo–KAGRA (LVK) collaboration. The LIGO observatories are funded by the National Science Foundation (NSF), and were conceived, built, and are operated by Caltech and MIT.<

The latest finding also indicates that collisions involving lightweight black holes may be more common than previously believed.

"This detection, the first of our exciting results from the fourth LIGO–Virgo–KAGRA observing run, reveals that there may be a higher rate of similar collisions between neutron stars and low mass black holes than we previously thought," says Jess McIver, an assistant professor at the University of British Columbia, deputy spokesperson of the LIGO Scientific Collaboration, and a former postdoctoral fellow at Caltech.

Prior to the GW230529 event, one other intriguing mass-gap candidate object had been identified. In that event, which took place in August 2019 and is known as GW190814, a compact object of 2.6 solar masses was found as part of a cosmic collision, but scientists are not sure if it was a neutron star or black hole.

After a break for maintenance and upgrades, the detectors' fourth observing run will resume on April 10, 2024, and will continue until February 2025.

The preprint GW230529 study titled, "Observation of Gravitational Waves from the Coalescence of a 2.5-4.5 M_\odot Compact Object and a Neutron Star," has been posted online.

Read the full story from the LVK collaboration.

Source: Caltech/News

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Contact:

>Whitney Clavin
(626) 395‑1944
wclavin@caltech.edu

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Versatile Instrument to Scout for Kuiper Belt Objects

This image of the Crab Pulsar was taken with CHIMERA, an instrument at the Palomar Observatory, which is operated by the California Institute of Technology. Credit: NASA/JPL-Caltech.  › Full image and caption

At the Palomar Observatory near San Diego, astronomers are busy tinkering with a high-tech instrument that could discover a variety of objects both far from Earth and closer to home.

The Caltech HIgh-speed Multi-color camERA (CHIMERA) system is looking for objects in the Kuiper Belt, the band of icy bodies beyond the orbit of Neptune that includes Pluto. It can also detect near-Earth asteroids and exotic forms of stars. Scientists at NASA's Jet Propulsion Laboratory and the California Institute of Technology, both in Pasadena, are collaborating on this instrument.

"The Kuiper Belt is a pristine remnant of the formation of our solar system," said Gregg Hallinan, CHIMERA principal investigator at Caltech. "By studying it, we can learn a large amount about how our solar system formed and how it's continuing to evolve."

The wide-field telescope camera system allows scientists to monitor thousands of stars simultaneously to see if a Kuiper Belt object passes in front of any of them. Such an object would diminish a star's light for only one-tenth of a second while traveling by, meaning a camera has to be fast in order to capture it.

"Each of CHIMERA's cameras will be taking 40 frames per second, allowing us to measure the distinct diffraction pattern in the wavelengths of light to which they are sensitive," said Leon Harding, CHIMERA instrument scientist at JPL. "This high-speed imaging technique will enable us to find new Kuiper Belt objects far less massive in size than any other ground-based survey to date."

Hallinan's CHIMERA team at Caltech and JPL published a paper led by Harding describing the instrument this week in the Monthly Notices of the Royal Astronomical Society.

 

Astronomers are particularly interested in finding Kuiper Belt objects smaller than 0.6 miles (1 kilometer) in diameter. Since so few such objects have ever been found, scientists want to figure out how common they are, what they are made of and how they collide with other objects. The CHIMERA astronomers estimate that in the first 100 hours of CHIMERA data, they could find dozens of these small, distant objects.

Another scientific focus for CHIMERA is near-Earth asteroids, which the instrument can detect even if they are only about 30 feet (10 meters) across. Mike Shao of JPL, who leads the CHIMERA group's near-Earth asteroid research effort, predicts that by using CHIMERA on the Hale telescope at Palomar, they could find several near-Earth objects per night of telescope observation.

Transient or pulsing objects such as binary star systems, pulsing white dwarfs and brown dwarfs can also be seen with CHIMERA.

"What makes CHIMERA unique is that it does high-speed, wide-field, multicolor imaging from the ground, and can be used for a wide variety of scientific purposes," Hallinan said. "It's the most sensitive instrument of its kind." 

CHIMERA uses detectors called electron multiplying charged-coupled devices (EMCCDs), making for an extremely high-sensitivity, low-noise camera system. One of the EMCCDs picks up near-infrared light, while the other picks up green and blue wavelengths, and the combination allows for a robust system of scanning perturbations in starlight. The detectors are capable of running at minus 148 degrees Fahrenheit (minus 100 degrees Celsius) in order to avoid noise when imaging fast objects.

"Not only can we image over a wide field, but in other modes we can also image objects rotating hundreds of times per second," Harding said.

One of the objects the CHIMERA team used in testing the instrument's imaging and timing abilities was the Crab Pulsar. This pulsar is the end result of a star whose mass collapsed at the end of its life. It weighs as much as our sun, but spins 32 times per second. The instrument focused on the pulsar for a 300-second exposure to produce a color image.

"Our camera can image the entire field of view at 40 frames per second," Hallinan said. "We zoomed in on the pulsar and imaged it very fast, then imaged the rest of the scene slowly to create an aesthetically-pleasing image."

Highlighting CHIMERA's versatility, the instrument also imaged the globular cluster M22, located in the constellation Sagittarius toward the busy center of our galaxy. A single 25-millisecond image captured more than 1,000 stars. The team will be observing M22, and other fields like it, for 50 nights over three years, to look for signatures of Kuiper Belt objects.

Caltech manages JPL for NASA.

Media Contact

Elizabeth Landau
Jet Propulsion Laboratory, Pasadena, Calif.
818-354-6425
Elizabeth.Landau@jpl.nasa.gov

Source: JPL-Caltech