We investigate the evolution and interaction of voids in an Einstein-d
e Sitter universe. Using N-body simulations, we study the growth of di
fferent configurations of negative top-hat density perturbations. We f
ind that adjacent voids merge to form larger voids. Thin planar walls
form between the merging voids. The peculiar velocity is tangential to
a given wall and rises linearly from the wall center. The density con
trast of the walls steadily declines as the walls are stretched by the
greater rate of expansion within the new void resulting from the merg
er. A simple hierarchical configuration of negative perturbations demo
nstrates that smaller scale voids effectively disappear within larger
voids as larger scales become nonlinear. The remnants of previous stru
cture formation are frozen in within evolving voids. The evolution of
a void is not significantly affected by the collapse of a neighboring
positive perturbation of the same scale. The characteristic size of vo
ids which fill the volume of the universe at a given epoch has a narro
w distribution suggesting that the large-scale structure appears as a
network of close-packed voids of approximately the same size.