Researchers created tornado-like vortices in superfluid helium
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Giant quantum vortices could allow researchers to study black holes. This vortex is a special form of liquid helium vortex that exhibits quantum effects. The result has some properties similar to a black hole and acts as a kind of simulator.
In the region around a black hole, the laws of gravity and quantum mechanics interact, producing effects that cannot be observed elsewhere in the universe. This makes these regions particularly important to study. “There are interesting physics happening around black holes, but many of them are out of our reach,” he says. Silke Weinfurtner at the University of Nottingham, UK. “Thus, we can use these quantum simulators to investigate phenomena that occur around black holes.”
To build the quantum simulator, Weinfurtner and his colleagues used superfluid helium, which flows at a very low viscosity, 500 times lower than water. Because it moves without friction, this form of helium exhibits unusual quantum effects and is known as a quantum fluid. The researchers filled a tank with helium with a rotating propeller at the bottom. As the propeller rotated, a tornado-like vortex was generated in the fluid.
“Similar vortices have been created in physical systems other than superfluid helium, but their strength is generally at least several orders of magnitude weaker,” he says. Patrick Svanchara, is also enrolled at the University of Nottingham and is part of the team. The strength and size of the vortex are critical to producing an interaction significant enough to observe between the vortex and the remaining fluid in the tank.
The vortices in this work were a few millimeters in diameter, much larger than other stable vortices created to date. quantum fluid In the past. In quantum liquids, rotation only occurs in tiny “packets” called quanta, which are essentially tiny vortices, so creating such large vortices is difficult. Many of them tend to become unstable when clustered, but the experimental setup here allows the researchers to combine about 40,000 rotating quanta to form what is called a giant quantum vortex. It's done.
“This is an experimental masterpiece,” he says Jeff Steinhauer He received his PhD from the Technion-Israel Institute of Technology, a pioneer in laboratory simulations of black holes. “They took a very well-established, old, classic technology called superfluid helium and did something really new with it, significantly increasing their technical capabilities compared to what had been done in the past. .”
The researchers observed how small waves in the fluid interacted with vortices. This process mimics the way the universe's cosmic field interacts with a rotating black hole. They discovered hints of a black hole phenomenon called ringdown mode. This phenomenon occurs after two black holes combine and the resulting single black hole is shaken by the residual energy of the combination.
Now that it has been established that this type of vortex exhibits behavior similar to that seen in black holes, researchers plan to use quantum vortices to study more elusive phenomena. “This is an excellent starting point for investigating some black hole physics processes, seeking new insights and potentially discovering hidden treasures along the way,” Weinfurtner says. .
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Source: www.newscientist.com
