We present results from a direct numerical simulation of the passive transp
ort of solid particles by a fully developed turbulent channel flow with a R
eynolds number of 180 based on the friction velocity and the channel half-w
idth. Three particle sets are studied, ranging in diameter from 0.5 to 1.4
viscous wall units and in aerodynamic time constant from 0.6 to 56 centreli
ne Kolmogorov time scales. We use particle number density histograms and fr
actal dimensions to show that the level of order in the particle spatial di
stribution peaks near a Stokes number of unity based on the Kolmogorov time
scale. We then quantify the relationship between this spatial distribution
and the instantaneous flow topology. The results indicate that the previou
sly reported preferential concentration of particles in low-speed streaks l
eads to a suppression of particle velocities in the viscous sublayer and bu
ffer region even in the presence of streamwise gravitational acceleration.
In other regions of the flow, the particles' non-random spatial distributio
n is shown to be uncorrelated with the local flow topology. We compare our
results with the experimental data of Kulick et al. (1994) and Fessler et a
l. (1994) and confirm that the latter authors' results were not influenced
by turbulence modification.