Some isolated Wolf-Rayet stars present random variability in their optical
flux and polarization. We make the assumption that such variability is caus
ed by the presence of regions of enhanced density-i.e., blobs-in their enve
lopes. In order to find the physical characteristics of such regions, we ha
ve modeled the stellar emission using a Monte Carlo code to treat the radia
tive transfer in an inhomogeneous electron scattering envelope. We are able
to treat multiple scattering in the regions of enhanced density as well as
in the envelope itself. The finite sizes of the source and structures in t
he wind are also taken into account. Most of the results presented here are
based on a parameter study of models with a single blob. The effects cause
d by multiple blobs in the envelope are considered to a more limited extent
. Our simulations indicate that the density enhancements must have a large
geometric cross section in order to produce the observed photopolarimetric
variability. The sizes must be of the order of 1 stellar radius, and the bl
obs must be located near the base of the envelope. These sizes are the same
inferred from the widths of the subpeaks in optical emission lines of Wolf
-Rayet stars. Other early-type stars show random polarimetric fluctuations
with characteristics similar to those observed in Wolf-Rayet stars, which m
ay also be interpreted in terms of a clumpy wind. Although the origin of su
ch structures is still unclear, the same mechanism may be working in differ
ent types of hot star envelopes to produce such inhomogeneities.