In the phase field model of binary solidification the mobility terms which
appear in the governing rate equations can be estimated from the liquid dif
fusion coefficients of the pure elements and the velocity of the solid-liqu
id interface as a function of undercooling. Molecular dynamics simulations
utilizing embedded atom potentials have been employed to compute the liquid
diffusivities for pure Cu and Ni in the vicinity of their melting points.
In both cases the diffusion coefficient is found to vary linearly with temp
erature and the results are in good agreement with experimental values whic
h are available for Cu. The simulations were also employed to obtain the bo
undary velocities in three different low index growth directions. The resul
ts for Cu and Ni were found to be very similar, with the slope of the veloc
ity-undercooling curve at small undercoolings varying in the range 45-18 cm
/s/K. Anisotropy in the growth behavior was observed with V-100 > V-110 > V
-111. The solid-liquid interface velocities were found to be a factor of 4-
5 less than the theoretical upper limit derived previously. Published by El
sevier Science Ltd on behalf of Acta Metallurgica Inc.