A new simulation of supermassive black holes—the behemoths at the centers of galaxies—uses a realistic scenario to predict the light signals emitted in the surrounding gas before the masses collide, said Rochester Institute of Technology researchers.

The RIT-led study represents the first step toward predicting the approaching merger of supermassive black holes using the two channels of information now available to scientists—the electromagnetic and the gravitational wave spectra—known as multimessenger astrophysics. The findings appear in the paper “Quasi-periodic Behavior of Mini-disks in Binary Black Holes Approaching Merger,” published in the Astrophysical Journal Letters.

“We’ve performed the first simulation in which an accretion disk around a binary black hole feeds individual accretion disks, or mini-disks, around each black hole in general relativity and magnetohydrodynamics,” said Dennis Bowen, lead author and postdoctoral researcher at RIT’s Center for Computational Relativity and Gravitation.

Unlike their less massive cousins, first detected in 2016, supermassive black holes are fed by gas disks that surround them like doughnuts. The strong gravitational pull of the black holes that inspiral toward one another heats and disrupts the flow of gas from disk to black hole and emits periodic signals in the visible to X-ray portions of the electromagnetic spectrum.

“We have not yet seen two supermassive black holes get this close,” Bowen said. “It provides the first hints of what these mergers will look like in a telescope. The filling and refilling of mini-disks affect the light signatures.”

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The simulation models supermassive black holes in a binary pair, each surrounded by its own gas disks. A much larger gas disk encircles the black holes and disproportionately feeds one mini-disk over another, leading to the filling-and-refilling cycle described in the paper.

“The evolution is long enough to study what the real science outcome would look like,” said Manuela Campanelli, director of the Center for Computational Relativity and Gravitation and a co-author on the paper.

Binary supermassive black holes emit gravitational waves at lower frequencies than stellar-mass black holes. The ground-based Laser Interferometer Gravitational-wave Observatory, in 2016, detected the first gravitational waves from stellar mass black holes collisions with an instrument tuned to higher frequencies. LIGO’s sensitivity is unable to observe the gravitational wave signals produced by supermassive black hole coalescence.

The launch of the space-based Laser Interferometer Space Antenna, or LISA, slated for the 2030s, will detect gravitational waves from colliding supermassive black holes in the cosmos. When operational in the 2020s, the ground-based Large Synoptic Survey Telescope, or LSST, under construction in Cerro Pachón, Chile, will produce the widest, deepest survey of light emissions in the universe. The pattern of signals predicted in the RIT study could guide scientists to orbiting pairs of supermassive black holes.

“In the era of multimessenger astrophysics, simulations such as this are necessary to make direct predictions of electromagnetic signals that will accompany gravitational waves,” Bowen said. “This is the first step toward the ultimate goal of simulations capable of making direct predictions of the electromagnetic signal from binary black holes approaching merger.”


Provided by:
Rochester Institute of Technology

More information:
Dennis B. Bowen et al. Quasi-periodic Behavior of Mini-disks in Binary Black Holes Approaching MergerThe Astrophysical Journal (2018). DOI: 10.3847/2041-8213/aaa756

Image:
Two supermassive black holes at the center of a large gas disk are on a collision course in a time sequence simulated by RIT scientists. An alternating flow of gas fills and depletes mini disks feeding the black holes, shown above. Characteristic light signals emitted in the gas could mark the location of the invisible masses. (Note: The dot at the center of the image is not part of the simulation.)
Credit: RIT Center for Computational Relativity and Gravitation