Transport properties of isotropic fluids composed of hard ellipsoids o
f revolution are studied using molecular dynamics simulation. The self
-diffusion coefficient, the shear viscosity, and the thermal conductiv
ity are evaluated for a range of densities and elongations and are com
pared with the results from an Enskog kinetic theory for nonspherical
bodies. The full anisotropic pair correlation function, which is requi
red input in an Enskog kinetic theory, can be obtained from simulation
or can be approximated. If the pair correlation function is taken as
isotropic on the contact surface, with a contact value derived from an
accurate equation of state, the resulting kinetic theory transport pr
operties agree to within a few percent of those calculated on the basi
s of the exact pair correlation function. The simulation and the kinet
ic theory values for the shear viscosity and the thermal conductivity
show the same qualitative behavior, i.e., increasing with density and
with particle nonsphericity. Quantitatively, there is good agreement a
t low densities (up to 30% of closest packing); at higher densities (6
0% of closest packing), deviations from Enskog theory are larger than
and in the opposite direction to those seen for hard spheres. The Stok
es-Einstein and Debye relations are tested and indicate a transition r
om a kinetic theory region towards the hydrodynamic limit as density i
ncreases.