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Literature DB >> 12785954

Diffusion in a metallic melt at the critical temperature of mode coupling theory.

Volker Zöllmer¹, Klaus Rätzke, Franz Faupel, Andreas Meyer.

Abstract

According to mode coupling theory, liquidlike motion becomes frozen at a critical temperature T(c) well above the caloric glass transition temperature T(g). Here, for the first time, we report on radiotracer diffusion in a supercooled Pd43Cu27Ni10P20 alloy from T(g) to the equilibrium melt. Liquidlike motion is seen to set in exactly above T(c) as evidenced by a gradual drop of the effective activation energy. This strongly supports the mode coupling scenario. Isotope effect measurements, which have never been carried out near T(c) in any material, show atomic transport up to the equilibrium melt to be far away from the hydrodynamic regime of uncorrelated binary collisions.

Entities: Chemical

Year: 2003 PMID： 12785954 DOI： 10.1103/PhysRevLett.90.195502

Source DB: PubMed Journal: Phys Rev Lett ISSN： 0031-9007 Impact factor: 9.161

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Cited

5 in total

Review 1. The Interplay between the Theories of Mode Coupling and of Percolation Transition in Attractive Colloidal Systems.

Authors: Francesco Mallamace; Giuseppe Mensitieri; Martina Salzano de Luna; Paola Lanzafame; Georgia Papanikolaou; Domenico Mallamace
Journal: Int J Mol Sci Date: 2022-05-10 Impact factor: 6.208

Diffusion in a metallic melt at the critical temperature of mode coupling theory.

Review 1. The Interplay between the Theories of Mode Coupling and of Percolation Transition in Attractive Colloidal Systems.

2. A computational study of diffusion in a glass-forming metallic liquid.

3. Experimental evidence of low-density liquid water upon rapid decompression.

4. Thin-film metallic glass: an effective diffusion barrier for Se-doped AgSbTe₂ thermoelectric modules.

5. Glassy dynamics of sticky hard spheres beyond the mode-coupling regime.

Diffusion in a metallic melt at the critical temperature of mode coupling theory.

Review 1. The Interplay between the Theories of Mode Coupling and of Percolation Transition in Attractive Colloidal Systems.

2. A computational study of diffusion in a glass-forming metallic liquid.

3. Experimental evidence of low-density liquid water upon rapid decompression.

4. Thin-film metallic glass: an effective diffusion barrier for Se-doped AgSbTe2 thermoelectric modules.

5. Glassy dynamics of sticky hard spheres beyond the mode-coupling regime.

4. Thin-film metallic glass: an effective diffusion barrier for Se-doped AgSbTe₂ thermoelectric modules.