Dark Matter May Be Made of Primordial Black Holes

Infrared Background — This image shows the infrared background, or the infrared light not associated with known sources. It may be left over from the universe's first luminous objects, including stars.

(Image credit: NASA/JPL-Caltech/A. Kashlinsky (Goddard))

Could dark matter — the elusive substance that composes most of the material universe — be made of black holes? Some astronomers are beginning to think this tantalizing possibility is more and more likely.

Alexander Kashlinsky, an astronomer at the NASA Goddard Space Flight Center in Maryland, thinks that black holes that formed soon after the Big Bang can perfectly explain the observations of gravitational waves, or ripples in space-time, made by the Laser Interferometer Gravitational-Wave Observatory (LIGO) last year, as well as previous observations of the early universe.

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In 2005, Kashlinsky and his colleagues used NASA's Spitzer Space Telescope to explore the background glow of infrared light found in the universe. Because light from cosmic objects takes a finite amount of time to travel through space, astronomers on Earth see distant objects the way those objects looked in the past. Kashlinsky and his group wanted to look toward the early universe, beyond where telescopes can pick up individual galaxies.

Then, there was the LIGO detection. On Sept. 14, 2015, the observatory made the first-ever direct detection of gravitational waves — cosmic ripples in the fabric of space-time itself — that had been produced by a pair of colliding black holes. It marked the beginning of a new era of discovery — one in which astronomers could collect these unique signals created by powerful astronomical events and, for the first time, directly detect black holes (as opposed to seeing the illuminated material around black holes).

For now, these primordial black holes remain hypothetical. But Kashlinsky, impressed by Bird's suggestion, took the hypothesis a step further. In his new paper, published May 24 in The Astrophysical Journal Letters, Kashlinsky looked at the consequences that these primordial black holes would have had on the evolution of the cosmos. (Bird is not the first scientist to suggest that dark matter might be made of black holes, although not all of those ideas involve primordial black holes.)

The infrared glow would come from the earliest stars that formed within the halos. Although stars radiate optical and ultraviolet light, the expansion of the universe naturally stretches that light so that the first stars will appear, to astronomers on Earth, to give off an infrared light. Even without the extra halos, early stars could generate an infrared glow, but not to the extent that Kashlinsky and his colleagues observed, he said.

The gas that created those stars would also have fallen onto the primordial black holes, heating up to high enough temperatures that it would have sparked X-rays. While the cosmic infrared background can be explained — albeit to a lesser extent — without the addition of primordial black holes, the cosmic x-ray background cannot. The primordial black holes connect the two observations together.

Occasionally, those primordial black holes would have come close enough to start orbiting each other (what's known as a binary system). Over time, those two black holes would spiral together and radiate gravitational waves, potentially like the ones detected by LIGO. But more observations of black holes are needed to determine if these objects are primordial, or formed later in the universe's history.