Transport Properties of Tetrahedral, Network-Forming Ionic Melts

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• 作者：Manish Agarwal ; Abir Ganguly ; Charusita Chakravarty
• 刊名：Journal of Physical Chemistry B
• 出版年：2009
• 出版时间：November 19, 2009
• 年：2009
• 卷：113
• 期：46
• 页码：15284-15292
• 全文大小：492K
• 年卷期：v.113,no.46(November 19, 2009)
• ISSN：1520-5207

文摘

Molecular dynamics simulations of liquid silica and beryllium fluoride are performed using the van Beest−Kramer−van Santen and transferable rigid ion model potentials, respectively, in order to compare transport properties. The ionic conductivity (σ), shear viscosity (η) and ionic self-diffusivities (D_±) are computed over a fairly wide range of temperatures and densities and deviations from Arrhenius behavior along different isochores is studied. The Stokes−Einstein relation is shown to hold over the entire range of state points, though the effective hydrodynamic radius shows small variations due to thermal fluctuations, compression, and local tetrahedral order. Several alternative tests of the Nernst−Einstein relation are implemented which show that significant network-formation in the anomalous regime leads to a breakdown of this relationship. The relaxation times, τ_σ and τ_M, associated with the decay of the charge-flux and pressure ACFs respectively, are computed. In the anomalous regime, as the tetrahedral network formation progresses, τ_M increases rapidly while τ_σ shows very little variation, indicating a decoupling of charge and momentum transport processes.