麻豆视频

Binary black hole spin behavior revealed using novel techniques

Physics

By | Kate Blackwood , Cornell Chronicle

Research done at Cornell has uncovered from gravitation wave data the first potential signs of spin-orbit resonances in binary black holes, a step toward understanding the mechanisms of supernovas and other big questions in astrophysics.

"These resonances were predicted over a decade ago using Einstein鈥檚 theory of general relativity,鈥 said . A former Klarman Postdoctoral Fellow in the 麻豆视频 & 麻豆视频 (A&S), Varma analyzes gravitational waves detected by the L (LIGO) and the in order to learn more about binary black holes. 鈥淲e find the first 鈥榟ints鈥 of the resonances in gravitational wave data from LIGO and Virgo.鈥

The rate at which a black hole spins reveals a lot about its history, Varma said: for black holes arranged in an interactive pair, called a binary, the direction of each black hole鈥檚 spin is also revelatory, especially in relation to one another.

In 鈥,鈥 published January 19 in Physical Review Letters, Varma and collaborators report that the two black holes鈥 spins, when projected onto the orbital plane, tend to be anti-parallel to each other, which can be a signature of spin-orbit resonances. More observations are needed to confirm these tendencies, Varma said.

Varma conducted much of this research while a Klarman Fellow; he is now a Marie Curie fellow at the Max Planck Institute for Gravitational Physics. Collaborators on this work include Syliva Biscoveanu, Maximiliano Isi and Salvatore Vitale from the Massachusetts Institute of Technology and Will Farr from the Flatiron Institute.

鈥淩esonance effects are ubiquitous in physical systems. They occur when two processes in a system occur at specially related frequencies,鈥 said , the Hans A. Bethe Professor of Physics (A&S), Varma鈥檚 faculty mentor at Cornell. 鈥淚n the black hole systems that Vijay is studying, the resonance is predicted to occur between the spin motion of the black holes and their orbital motion, and leaves an imprint on the gravitational waves produced. This work shows that if we analyze the data cleverly, we are much closer to testing this prediction of General Relativity than we thought we were.鈥

Black holes typically rotate (spin) because they form from dying stars that spin themselves, Varma said. When two such black holes orbit each other in a binary, their spins interact with the orbit.

Binary black holes lose energy to gravitational waves, causing the black holes to move toward each other and eventually merge, Varma said. Some binary black hole spins are aligned along or opposite the orbital angular momentum, leading to a 鈥渂land鈥 merger on a fixed plane. But other binary black holes have spins tilted with respect to the orbital angular momentum, setting off an intricate interaction called precession.

鈥淲hen the spins are tilted with respect to the orbital angular momentum, the orbit precesses like a top that is spinning along a tilted axis,鈥 Varma said.

Spin-orbit resonances can occur in precessing binaries, but this depends on the nature of the supernova mechanism that produces the black holes from their stellar progenitors, Varma said. If the supernova emission is not symmetric in all directions, the black hole gets a recoil velocity at birth, which is similar to the recoil of a fired gun.

鈥淚f the supernova recoils are large enough, the binary can end up in a spin-orbit resonance,鈥 Varma said. 鈥淭hese are special configurations where the spins directions in the orbital plane are either parallel or anti-parallel.鈥

It was thought that LIGO and Virgo gravitational wave detectors were not sensitive enough to pick up evidence of spin-orbit resonances. However, Varma and collaborators applied two data-gathering hacks in order to detect these first hints.

First, Varma applied computer modeling based on simulations of black holes.

鈥淰ijay is a world expert at developing what are called 鈥榮urrogate models,鈥 Teukolsky said .

Varma said: 鈥淭hese models accurately capture the effect of the spins from numerical simulations. They allow us to extract as much of this information as possible from gravitational wave observations.鈥

Second, the researchers learned to measure the spins just before the black holes merge, rather than the standard practice of measuring spins many orbits before the merger. This method of late spin measurement is the topic of a companion paper, 鈥,鈥 published January 19 in Physical Review D.

鈥淲e are starting to probe the spin-orbit resonances, which we originally thought was impossible until next-generation detectors arrive in the 2030s,鈥 Varma said. 鈥淥ur hope is that by studying these spin-orbit resonances, we can learn more about the mechanism of the supernova, which has remained an enduring mystery.鈥

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Illustration of two black holes
LIGO/Caltech/MIT/Sonoma State (Aurore Simonnet) An artist's conception of a precessing binary black hole. The black holes, which will ultimately spiral together into one larger black hole, are shown here orbiting one another in a plane. The black holes are spinning in a non-aligned fashion, which means they are tilted relative to the overall orbital motion of the pair. This causes the orbit to precess like a top spinning along a tilted axis.