In the presence of a suitable nucleating agent, a liquid in a metastable state below its thermodynamically defined melting point freezes. That’s what happens when atmospheric aerosol particles in clouds cause supercooled water droplets to form snowflakes. Researchers have suspected that the atomic surface structure of the seeding particles acts as a template, inducing local order in the disordered liquid and catalyzing its crystallization. Conversely, a solid with a different structure can inhibit crystallization, as has now been observed at the European Synchrotron Radiation Facility in Grenoble, France, by Tobias Schülli and his colleagues. The researchers coupled x-ray scattering data with molecular-dynamics simulations to study supercooled goldsilicon droplets on a silicon substrate, a system that is used to grow Si nanowires. Surprising results emerged when they heated the AuSi alloy above 676 K: As it cooled, the Si atoms leached onto the substrate and, as the figure shows, rearranged its...
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1 June 2010
June 01 2010
Delayed freezing in a supercooled liquid metal
Physics Today 63 (6), 18 (2010);
Citation
Jermey N. A. Matthews; Delayed freezing in a supercooled liquid metal. Physics Today 1 June 2010; 63 (6): 18. https://doi.org/10.1063/1.4796267
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