March 29, 2024

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A physics experiment inspired by Earth’s core leads to a groundbreaking discovery in fluid flow turbulence

A physics experiment inspired by Earth’s core leads to a groundbreaking discovery in fluid flow turbulence

Physicists have discovered a new aspect of turbulent convection, showing that it can cause a solid inside a liquid to rotate freely in two directions, sometimes shifting due to turbulence. This research, which has implications for understanding the flow of fluids from the Earth’s core to boiling water, also highlights the key role that convection may play within the Earth and the possibility of controlling turbulence by interaction with solids.

Turbulent flows take a surprising spin on a core-inspired experience.

A team of physicists has discovered a new role for a specific type of turbulence – a finding that sheds light on flows of fluids ranging from Earth’s liquid core to boiling water.

Research that appears in the journal Proceedings of the National Academy of Sciencescentered on turbulent convection – the movement of fluids when heated from below.

John Zhang, Professor of Mathematics and Physics[{” attribute=””>New York University and NYU Shanghai, the paper’s senior author.

The study, which also included Kaizhe Wang, a researcher in NYU’s Department of Physics, focused specifically on Rayleigh–Bénard convection—a type of convection driven by temperature differences.

Turbulence Flows Cylindrical Container

A recent experimental study, inspired by the super-rotation of the Earth’s solid core, shows when turbulence flows contained in a cylinder interact with a free body a surprisingly smooth rotation is observed. The red (warm) and blue (cold) ribbons represent water flows. Credit: Kaizhe Wang and Jun Zhang

In their experiments, conducted in the Joint Research Institute of NYU Shanghai, the paper’s authors used a cylindrical container filled with water, then heated it from the bottom, creating convective flows. The resulting turbulent flows interacted with a suspended solid (a rectangular panel) that moved freely inside the container—a setting that allowed the researchers to better study how turbulent flows interact with solid structures within.

“Surprisingly, the system becomes somewhat well-behaved,” notes Zhang. “We observed a smooth rotation of the flows and the free solid.”

Their results showed that turbulent convection-powered flows, together with the solid, can move in two directions—one clockwise and the other counterclockwise—with the co-rotational speed increasing with the intensity of the convection. More than that, their rotation can sometimes switch directions, caused by the turbulence.

“The research, inspired by the rotation of Earth’s inner core as it interacts with the convective liquid core, captures the interaction between a turbulent flow and a freely moving body within the flow,” explains Zhang. “The findings confirm that turbulence can be tamed by interacting with solids. It also reminds us that the power of thermal convection might play more important roles inside our planet Earth.”

Reference: “Persistent corotation of the large-scale flow of thermal convection and an immersed free body” by Kaizhe Wang and Jun Zhang, 15 May 2023, Proceedings of the National Academy of Sciences.
DOI: 10.1073/pnas.2217705120

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