This animation, created with supercomputers at the University of Colorado, Boulder, show for the first time what happens to the magnetized gas clouds that surround supermassive black holes when two of them collide.

The simulation shows the magnetic fields intensifying as they contort and twist turbulently, at one point forming a towering vortex that extends high above the center of the accretion disk. This funnel-like structure may be partly responsible for the jets that are sometimes seen erupting from voracious supermassive black holes.

The simulation was created to study what sort of "flash" might be made by the merging of such incredibly massive objects, so that astronomers hunting for evidence of gravitational waves — a phenomenon first proposed by Einstein in 1916 — will be able to better identify their potential source.

Gravitational waves are often described as "ripples" in the fabric of space-time, infinitesimal perturbations created by supermassive, rapidly rotating objects like orbiting black holes. Detecting them directly has proven to be a challenge but researchers expect that the technology will be available within several years' time — and knowing how to spot colliding black holes will be the first step in identifying any gravitational waves that result from the impact.

The video here shows the expanding gravitational wave structure that would be expected to result from such a merger.

In fact, it's the gravitational waves that rob energy from the black holes' orbits, causing them to spiral into each other in the first place.

"The black holes orbit each other and lose orbital energy by emitting strong gravitational waves, and this causes their orbits to shrink. The black holes spiral toward each other and eventually merge," said astrophysicist John Baker, a research team member from NASA's Goddard Space Flight Center. "We need gravitational waves to confirm that a black hole merger has occurred, but if we can understand the electromagnetic signatures from mergers well enough, perhaps we can search for candidate events even before we have a space-based gravitational wave observatory."

If ground-based telescopes can pinpoint the radio and x-ray flash created by the mergers, future space telescopes — like ESA's eLISA/NGO — can then be used to try and detect the waves.

Read more on the NASA Goddard new release here.

First animation credit: NASA's Goddard Space Flight Center/P. Cowperthwaite, Univ. of Maryland. Second animation: NASA/C. Henze.

This article originally appeared at Universe Today.