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Scientists from the University of Stuttgart (Germany)combinethe properties of gases, crystals and superfluids to a single unique state of matter.
The world of quantum mechanics happens only in small scales around a few nanometers. In this nanoworld, particles can behave like waves, and vice versa and have only some probability to be in a particular region. These effects can be directly observed in ultracold dilute gases. For this purpose thousands or a million atoms are cooled down to a few billionth of a degree above absolute zero. At such low temperatures particles become indistinguishable und unite collecitvely to a single giant matter wavecalled Bose-Einstein condensate which has astonishing properties. The matter wave flows as quantum fluid practically without inner friction, thus it is namedsuperfluid.
Researchers around Tilman Pfau at the Center for Integrated Quantum Science and Technology IQSTin Stuttgart (Germany) created such a quantum fluid made of tiny magnets – that areatoms of the most magnetic element dysprosium. They call it “quantum ferrofluid” since it is superfluid and has magnetic properties similar to classical ferrofluids. Ferrofluids consist of ferromagnetic nanoparticles dissolved in oil or water. When a strong magnetic field is applied perpendicular to the surface of the ferrofluid it undergoes a so-called Rosensweig instability. The surface is no longer smooth like normal fluids, but it generates a regular thorny surface resembling a hedgehog. From the point view of the tiny magnets in a ferrofluid, every south- and northpole attract each other. Therefore, it is energetically favourable to be on top of each other along the field direction, so the fluid grows peaks out of the smooth surface.
For their investigations, described in the science journal “Nature”, the researchers from Stuttgart created a quantum ferrofluid with 15,000 atoms and induced a magnetic instability. They observedthen the emergence of regular patterns consisting ofmicroscopic droplets, similar to the Rosensweig instability of ferrofluids. Each droplet has a radius smaller than 1 µmand theirexistence was not expected with the current state of research on these systems.Their observation could thus lead to a new field of research, as the researchers expect quantum fluctuations, related to Heisenberg’s uncertainty principle,to play an important role in the droplet existence.These quantum fluctuations allow a unique state of matter that connects opposite properties of gases, crystals and superfluids. This connectioncould be the path to a so-called supersolid, a spatially ordered material with superfluid properties.
Kontakt: Prof. Dr. Tilman Pfau, Universität Stuttgart, 5. Physikalisches Institut, Tel. 0711/685-68025, E-Mail: t.pfau (at) physik.uni-stuttgart.de
Merkmale dieser Pressemitteilung:
Journalisten
Physik / Astronomie
überregional
Forschungsergebnisse
Englisch
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