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Surprising turbulence by Staff Writers Dresden, Germany (SPX) May 20, 2022
Some metals are in liquid form, the prime example being mercury. But there are also enormous quantities of liquid metal in the Earth's core, where temperatures are so high that part of the iron is molten and undergoes complex flows. A team at the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) has now simulated a similar process in the laboratory and made a surprising discovery: Under certain circumstances, the flow of liquid metal is far more turbulent than expected - and this has a significant impact on heat transport, presents the group in the journal Physical Review Letters. The editors found this new finding so remarkable that they highlighted the article as "Editor's Suggestion". Temperatures deep inside the Earth are so high that part of its iron core is liquid. This liquid iron is in constant motion, continuously churning and circulating. It acts like a dynamo, causing our planet's magnetic field to be generated. One driving force for this complex flow behavior of iron is the Earth's rotation, another is what is referred to as "convection", driven by temperature differences: Similar to the way warm air rises above a radiator, where it displaces cooler air, relatively hot iron in the Earth's core flows to cooler areas, resulting in heat transfer. As yet, however, little is known about how these processes take place in detail. To better understand them, experts have to rely on theoretical calculations and computer simulations, as well as experiments that simulate what is happening - at least to some extent - on a laboratory scale. One such experiment was conducted recently at the HZDR's Institute of Fluid Dynamics. "We took two cylindrical vessels - a relatively small one about the size of a bucket and the other one shaped like a barrel with a volume of 60 liters," explained project leader Dr. Tobias Vogt. "We filled these vessels with a metallic alloy of indium, gallium and tin, which is liquid at room temperature." The experts heated the bottom of the vessels whilst cooling the top, creating a temperature difference of up to 50 degrees Celsius between the higher and lower layers.
Ultrasound provides in-depth view When analyzing the data, the research group made a surprising discovery. During the experiments, the experts had expected to find the clustering of individual flow areas to form a greater, more extensive structure, known as large-scale circulation. "This is comparable to a thermal wind, which is able to transport heat very effectively between the top and the bottom," reported Vogt. "We were indeed able to observe this thermal wind in the smaller vessel - but with the larger vessel, the barrel, large temperature differences led to an almost complete breakdown of the wind." This meant that heat was not transported as effectively as would have been expected. "We believe the cause of this to be the formation of much smaller-scale turbulence rather than a few large swirls, which makes heat transport less effective", stated Vogt.
Implications for battery technology "However, the real-life processes in the Earth's core are many times more complex than in our laboratory experiments," Tobias Vogt added. "For example, the flow of liquid iron is also influenced by the Earth's magnetic field and rotation - ultimately, we know very little about these flow processes." In fact, the new findings could also prove relevant for technology, especially in areas involving liquid metals. For example, liquid metals are used in some types of batteries as well as for future solar power plants, and cool fusion reactors. To be able to take an even closer look at heat transport in liquid metals, the HZDR team are currently working on an advanced analytical technique. "Special induction sensors are expected to record flows in even greater detail than before and produce true 3D images," remarked Sven Eckert. "Our initial measurements are very promising."
Research Report:Collapse of Coherent Large Scale Flow in Strongly Turbulent Liquid Metal Convection
Ultracold Bubbles on Space Station Open New Avenues of Quantum Research Pasadena CA (JPL) May 19, 2022 Since the days of NASA's Apollo program, astronauts have documented (and contended with) how liquids behave differently in microgravity than they do on Earth - coalescing into floating spheres instead of bottom-heavy droplets. Now, researchers have demonstrated this effect with a much more exotic material: gas cooled to nearly absolute zero (minus 459 degrees Fahrenheit, or minus 273 degrees Celsius), the lowest temperature matter can reach. Using NASA's Cold Atom Lab, the first-ever quantum physi ... read more
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