Non-thermal melting in semiconductors measured at femtosecond resolution

Ultrafast time-resolved optical spectroscopy has revealed new classes of physical, chemical and biological reactions, in which directed, deterministic motions of atoms have a key role. This contrasts with the random, diffusive motion of atoms across activation barriers that typically determines kine...

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Bibliographic Details
Published in:Nature (London) 2001-03, Vol.410 (6824), p.65-68
Main Authors: Rousse, A, Hulin, D, Balcou, Ph, Sebban, S, Uschmann, I, Gauthier, J.C, Fourmaux, S, Grillon, G, Rischel, C, Geindre, J.P, Förster, E, Audebert, P
Format: Article
Language:English
Subjects:
Atoms & subatomic particles
Condensed matter: structure, mechanical and thermal properties
Equations of state, phase equilibria, and phase transitions
Exact sciences and technology
Humanities and Social Sciences
Kinetic energy
letter
Melting
multidisciplinary
Optics
Physics
Science
Science (multidisciplinary)
Scientific imaging
Semiconductors
Solid-liquid transitions
Specific phase transitions
Spectroscopy
X-ray diffraction
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Summary:Ultrafast time-resolved optical spectroscopy has revealed new classes of physical, chemical and biological reactions, in which directed, deterministic motions of atoms have a key role. This contrasts with the random, diffusive motion of atoms across activation barriers that typically determines kinetic rates on slower timescales. An example of these new processes is the ultrafast melting of semiconductors, which is believed to arise from a strong modification of the inter-atomic forces owing to laser-induced promotion of a large fraction (10% or more) of the valence electrons to the conduction band. The atoms immediately begin to move and rapidly gain sufficient kinetic energy to induce melting-much faster than the several picoseconds required to convert the electronic energy into thermal motions. Here we present measurements of the characteristic melting time of InSb with a recently developed technique of ultrafast time-resolved X-ray diffraction that, in contrast to optical spectroscopy, provides a direct probe of the changing atomic structure. The data establish unambiguously a loss of long-range order up to 900  inside the crystal, with time constants as short as 350 femtoseconds. This ability to obtain the quantitative structural characterization of non-thermal processes should find widespread application in the study of ultrafast dynamics in other physical, chemical and biological systems.
ISSN:0028-0836
1476-4687
DOI:10.1038/35065045