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Turbulence (seen here in cyclones) ... is described as the oldest unsolved problem in physics. Image by WikiImages from Pixabay
Turbulence (seen here in cyclones) ... is described as the oldest unsolved problem in physics. Image by WikiImages from Pixabay
20 December 2019

University of Queensland researchers have combined quantum liquids and silicon-chip technology to study turbulence for the first time, opening the door to new navigation technologies and improved understanding of the turbulent dynamics of cyclones and other extreme weather.

Professor Warwick Bowen, from Õ¬Äе¼º½’s and the said the finding was “a significant advance” and provided a new way to study turbulence.

“Turbulence is often described as the oldest unsolved problem in physics,” Professor Bowen said.

“Our finding allows us to observe nanoscale quantum turbulence, which mirrors the sort of behaviour you see in cyclones.

Artists' impression of quantum vortices in a liquid. These are the quantum equivalent of vortices in water or a tornado. Their interactions cause dynamics analogous to that of a cyclone. Image: Christopher Baker“This advance is enabled by the properties of quantum liquids, which are fundamentally different to everyday liquids.”

Professor Bowen said it was postulated more than 50 years ago that the turbulence problem could be simplified using quantum liquids.

“Our new technique is exciting because it allows quantum turbulence to be studied on a silicon chip for the first time,” he said.

The research also had implications in space, where quantum liquids are predicted to exist within dense astrophysical objects.

“Our research could help to explain how these objects behave,” Dr Bowen said.

, the paper’s lead author, said rotating neutron stars lost angular momentum in fits and starts.

“The way this occurs is thought to hinge on quantum turbulence,” Dr Sachkou said.

, who co-led the research, said the finding made possible silicon-chip based accelerometers with sensitivity far beyond current state of the art.

“In quantum liquids, atoms behave more like waves than particles,” Dr Baker said.

“This allows us to build laser-like sensors from atoms.”

The research was a collaboration between researchers in the ARC Centre of Excellence for Engineered Quantum Systems (EQUS) and ARC Centre of Excellence in Future Low-Energy Electronic Technologies (FLEET) in Australia, and the Dodd-Walls Centre for Photonic and Quantum Technologies in New Zealand. It was supported by the United States Army Research Office and the , and was published today in Science.

, titled Simulations of the dynamics of quantised vortices -- the quantum analogue of a vortex in water or a tornado - as they interact on a silicon chip. (Credit: Dr Matthew Reeves.)

The paper, , is published today in .

Media: Professor Warwick Bowen, wbowen@physics.uq.edu.au, +61 404 618 722; Dr Chris Baker, chris.baker3@uq.edu.au, +61 466 654 598; Dominic Jarvis, dominic.jarvis@uq.edu.au, +61 413 334 924; Tara Roberson, comms@equs.org, +61 404 516 635.