C. Tasseven et al., INTEGRAL-EQUATIONS CALCULATIONS AND COMPUTER-SIMULATIONS OF THE STATIC STRUCTURE AND IONIC TRANSPORT IN MOLTEN NICKEL HALIDES, High-temperature materials and processes, 17(3), 1998, pp. 163-176
We present the first integral equations calculations and computer simu
lations of the static structure and ionic transport properties of molt
en nickel dihalides near melting. The calculations have been carried o
ut using the hypernetted chain theory of liquids (HNC), and for the si
mulations we have used molecular dynamics (MD). The potentials used fo
r the calculations have a similar functional form as the semiempirical
potentials originally proposed by Vashishta and Rahman in 1978 (Phys.
Rev. Lett., 40, 1337) to study alpha-AgI. The results for both the pa
ir distribution functions and partial structure factors are in fair ag
reement with experiment, except for the cation-cation partials where a
greement is poor, particularly at small momentum transfer. Most of, bu
t not all, the differences with experiment are likely to be due to the
use of a pairwise additive rigid ion model potential. There is, to ou
r knowledge, no experimental information on the ionic transport proper
ties for the NiX2 melts (X = Cl, Br, I). We believe that our predicted
results for the self-diffusion coefficients and ionic conductivity ar
e likely to overestimate the experimental values when these become ava
ilable. The results for the velocity autocorrelation functions suggest
a transport mechanism akin to that present in the alkali halides. We
find no evidence of remnants of superionic behaviour in molten NiI2.