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Neutron scattering and molecular correlations in a supercooled liquid

Guardat en:
Publicat a:arXiv.org (Feb 4, 1999), p. n/a
Autor principal: Theis, Christoph
Altres autors: Schilling, Rolf
Publicat:
Cornell University Library, arXiv.org
Matèries:
Neutrons
Diatomic molecules
Mathematical models
Structure factor
Molecular dynamics
Coupling (molecular)
Correlation
Dependence
Representations
Neutron scattering
Computer simulation
Scattering functions
Accés en línia:Citation/Abstract
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Resum:We show that the intermediate scattering function \(S_n(q,t)\) for neutron scattering (ns) can be expanded naturely with respect to a set of molecular correlation functions that give a complete description of the translational and orientational two-point correlations in the liquid. The general properties of this expansion are discussed with special focus on the \(q\)-dependence and hints for a (partial) determination of the molecular correlation functions from neutron scattering results are given. The resulting representation of the static structure factor \(S_n(q)\) is studied in detail for a model system using data from a molecular dynamics simulation of a supercooled liquid of rigid diatomic molecules. The comparison between the exact result for \(S_n(q)\) and different approximations that result from a truncation of the series representation demonstrates its good convergence for the given model system. On the other hand it shows explicitly that the coupling between translational (TDOF) and orientational degrees of freedom (ODOF) of each molecule and rotational motion of different molecules can not be neglected in the supercooled regime.Further we report the existence of a prepeak in the ns-static structure factor of the examined fragile glassformer, demonstrating that prepeaks can occur even in the most simple molecular liquids. Besides examining the dependence of the prepeak on the scattering length and the temperature we use the expansion of \(S_n(q)\) into molecular correlation functions to point out intermediate range orientational order as its principle origin.
ISSN:2331-8422
DOI:10.1103/PhysRevE.60.740
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