Black holes of 'all shapes and sizes' in new gravitational-wave catalog
Of the 35 new events observed between November 2019 and March 2020, 33 were likely mergers between black holes of various shapes and sizes. The other two events were likely black holes merging with neutron stars—a much rarer event. Of these rare black hole and neutron star mergers, one event appears to show a massive black hole (about 33 times the mass of our sun) merging with a very low-mass neutron star (about 1.17 times the mass of our sun). This is one of the lowest-mass neutron stars ever detected.
Since the first gravitational-wave detection in 2015, astrophysicists have detected a total of 90 events. By calculating the masses of the merging objects, astrophysicists can better understand how stars live and die and what makes them collapse into black holes versus neutron stars upon death.
"Only now are we starting to appreciate the wonderful diversity of black holes and neutron stars," said Christopher Berry, a key member of the Laser Interferometer Gravitational-Wave Observatory (LIGO) Scientific Collaboration (LSC). "Our latest results prove that they come in many sizes and combinations. We have solved some long-standing mysteries but uncovered some new puzzles too. Using these observations, we are closer to unlocking the mysteries of how stars—the building blocks of our universe—evolve."
The research is now available online, with two accompanying papers forthcoming. The team includes researchers from the LSC, the Virgo Collaboration and the Kamioka Gravitational Wave Detector (KAGRA) project.
An expert in gravitational-wave parameter estimation, Berry is a lecturer at the University of Glasgow and a visiting scholar at Northwestern's Center for Interdisciplinary and Exploratory Research in Astrophysics (CIERA). Other Northwestern astrophysicists involved with the latest catalog include Vicky Kalogera, the principal investigator of Northwestern's LSC group, director of CIERA and the Daniel I. Linzer Distinguished Professor of Physics and Astronomy in the Weinberg College of Arts and Sciences; Zoheyr Doctor, Board of Visitors Research Assistant Professor at CIERA; and Maya Fishbach, a NASA Einstein Postdoctoral Fellow and LSC member.
Albert Einstein first predicted gravitational waves in 1916, as a part of his theory of general relativity. But because the waves reaching Earth are so miniscule, it took researchers a century to build instruments precise enough to measure them.
Since the first detection in 2015 of two black holes merging, the number of detections has increased at a precipitous rate. In a matter of years, gravitational-wave scientists have gone from observing these vibrations in the fabric of the universe for the first time to now observing many events every month—sometimes even observing multiple events on the same day.
Gravitational-wave detectors operate by using high-power lasers to carefully measure the time taken for light to bounce between mirrors. In the third observing run, the gravitational-wave detectors reached their best-ever performance. To achieve this monumental progress, the pioneering instruments have been getting more sensitive thanks to a program of constant upgrades and maintenance.
"As our international network of interferometers become more sensitive and observe for longer, we are detecting more gravitational waves," said Doctor, co-chair of the rates and populations sub-group within the LIGO-Virgo-KAGRA collaboration. "From these very short, faint signals, we can learn a lot. We're starting to see rarer events and are beginning to unlock the diversity of black hole and neutron star mergers. Ultimately, we want to know how these exotic objects come to exist and collide with each other. These new detections are helping us zero in on that."
Filling in the picture of lower-mass objects
According to Doctor, the detectors' improved sensitivity is helping researchers find more mergers of lower-mass objects, which tend to be more difficult to detect. It also is helping researchers better define the boundaries of the puzzling area known as the "mass gap"—the range that lies between the heaviest known neutron star and the lightest known black hole.
"Our understanding of the properties and abundances of these lower-mass mergers has been fuzzy," Doctor said. "Now that we have actual hard detections, we're beginning to fill in that lower end of the mass spectrum."
The final gravitational-wave event in the latest catalog came from two objects merging, one almost certainly a black hole (with a mass around 24 times the mass of our sun) and the other either a very light black hole or a very heavy neutron star of around 2.8 times the mass of our sun. Scientists have deduced it is most likely to be a black hole, but they cannot be entirely sure.
In August 2019, LIGO and Virgo discovered a similar ambiguous event. The mass of the lighter object is puzzling, as scientists expect that the most massive a neutron star can be before collapsing to form a black hole is around 2.5 times the mass of our sun. However, no black holes had been discovered with electromagnetic observations with masses below about five solar masses. This led scientists to theorize that stars do not collapse to make black holes in this range. The new gravitational-wave observations indicate that these theories may need to be revised.
The future of the field
The LIGO and Virgo observatories are currently undergoing improvement works before the upcoming fourth observing run, expected to begin late 2022. The KAGRA observatory in Japan also will join the next full observing run. Located deep under a mountain, KAGRA completed a successful first observing run in 2020, but has yet to join LIGO and Virgo in making joint observations.
As more detections are confidently added to the gravitational-wave catalog, researchers are learning more and more about these astronomical phenomena. Before the next observing run, scientists will be busy further analyzing the existing information, learning more about neutron stars and black holes, and searching for new types of signals hidden in the data.
"It turns out that the gravitational-wave universe is incredibly exciting," Fishbach said. "Our upgraded detectors will be able to catch quieter signals, including black holes and neutron stars that merged even farther away, with signals from billions of years ago. I can't wait to discover what else is out there."
Provided by Northwestern University