Canonical ensemble molecular dynamics simulations of Lennard-Jones met
hane and ethane are conducted in an atomistic model of AlPO4-5, a mole
cular sieve with approximately cylindrical channels of diameter 7.3 An
gstrom. Methane molecules are able to pass each other in the nanopore
and exhibit unidirectional but otherwise ordinary diffusion along the
channel axis, with the mean-square displacement directly proportional
to time, and a diffusion coefficient calculated at a loading of 0.7 mo
lecules per unit cell at 295 K of 4.70 x 10(-4) cm(2) s(-1). Ethane mo
lecules cannot pass each other easily in the nanopore and for short ti
mes exhibit single-file diffusion, i.e., the mean-square displacement
is proportional to the square root of the time. After longer times, co
ntributions of ordinary unidirectional diffusion are observed due to t
he nonzero probability of passing. A slightly larger molecule exhibits
pure single-file diffusion. The single-file mobility for the large mo
lecule at 0.7 molecule per unit cell and 295 K is 1.57 x 10(-9) cm s(-
0.5). Effects of fluid density on absorbate mobility are also addresse
d. The density dependence of the single-file mobility is in agreement
with one-dimensional hard rod predictions.