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Exotic black holes caught turning into a superfluid

A model of a higher-dimensional black hole matches what happens when liquid helium loses all its stickiness, a coincidence that could help study both oddities
Artwork depicting conventional black hole with brightly coloured matter swirling around it
So conventional by comparison
Pasieka/Getty

The black holes in our universe may seem like bizarre, voracious beasts 鈥 but stranger ones are possible. Simulations of black holes have revealed the first superfluid specimen.

Superfluids are a form of matter that take mere melting one step further. When a solid turns to a liquid, what was once sturdy and inflexible begins to flow. Superfluids have zero stickiness or viscosity: they can even flow uphill. They also have completely uniform temperature.

But superfluids are extremely difficult to create. Only liquid helium has been coaxed into going superfluid, and then only at temperatures close to absolute zero. The stuff is even harder to study or model: many of the important calculations are ones that nobody knows how to do yet.

Now, at the University of Waterloo in Canada and his colleagues have modelled a theoretical black hole that changes in a way that鈥檚 mathematically identical to what liquid helium does when it turns superfluid.

These model black holes are exotic, existing in a higher-dimensional space-time with properties very different from our own. Given certain conditions for gravity鈥檚 interaction with matter, the switch to superfluidity could potentially happen in a wider set of black holes 鈥 but probably not ones in our universe.

鈥淚t鈥檚 thinkable that these conditions could be satisfied in our universe, but they鈥檙e probably not,鈥 says Mann.

Even so, simulating them is potentially illuminating. 鈥淭his could tell us something about superfluids which we can鈥檛 calculate by other methods, so that鈥檚 part of the excitement,鈥 says at the University of Massachusetts Amherst.

The other part is exactly the reverse: studying superfluids could teach us about how black holes behave at different temperatures and pressures. 鈥淵ou can see these thermodynamic things happening on the black hole side, and you can learn about them by knowing how thermodynamics works in the everyday world,鈥 says co-author , also at the University of Waterloo.

By using one enigma to model another, researchers are inching closer to an understanding of both.

Physical Review Letters

Topics: Absolute zero / Black holes