ScienceDaily (Nov. 9, 2012) ? A new way to make glass has been discovered by a collaboration of researchers at the Universities of D?sseldorf and Bristol using a method that controls how the atoms within a substance are arranged around each other.
The research is published November 9 in Physical Review Letters.
When cooling a liquid below its melting temperature it either crystallizes or transforms into a glass. Glass is a peculiar state of matter: it has the mechanical properties of a solid but an amorphous structure like a liquid.
As long ago as 1952, Sir Charles Frank at the University of Bristol argued that the structure of glasses should not be entirely disordered like a liquid but rather that it should be filled with structural motifs like the bicapped square antiprism [inset pictured].
Although such motifs have very recently been found in experiments and computer simulations on glassy materials, it has not been clear what role these play in how a liquid becomes a (glassy) solid.
The D?sseldorf and Bristol researchers created a new type of glass in a computer through encouraging atoms in a nickel-phosphorus alloy to form the pictured polyhedron. When these polyhedra formed, the liquid no longer flowed -- it had become a solid. In other words, they found that instead of cooling, a liquid can turn into a glass by changing its structure.
Dr Paddy Royall of the University of Bristol said: "The method we developed employed computer simulations of liquids, performed on the University of Bristol's BlueCrystal supercomputer, where the atoms were driven to form more polyhedra.
"Although many more polyhedra were formed, the atomic arrangements were still disordered rather than a periodic arrangement as seen in crystals. This means that the solid that was formed had to be a glass."
Dr Thomas Speck of Heinrich-Heine-Universit?t, D?sseldorf said: "These results mean that structure can control whether a material is liquid or solid and thus open the way to design new glasses: for example metallic glasses whose great lightness and strength promise exciting applications and chalcogenide glasses which are used in memory applications and phase switch memory, a possible future technology for data storage."
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The above story is reprinted from materials provided by University of Bristol.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
- thomas Speck, Alex Malins, and C. Patrick Royall. First-Order Phase Transition in a Model Glass Former: Coupling of Local Structure and Dynamics. Phys. Rev. Lett., 109, 195703 (2012) DOI: 10.1103/PhysRevLett.109.195703
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