Recent experimental results of Bhat and Narasimha (1996) have revealed a dr
amatic difference in the entrainment between jets and plumes subjected to o
ff-source volumetric heating and their unheated counterparts. Experimental
observations show that plumes entrain more rapidly than jets; the greater e
ntrainment by the plume is typically attributed to the presence of buoyancy
in the plume. In contrast, the addition of buoyancy away from the source b
y volumetric heating produces the opposite effect of reduced entrainment. A
part from buoyancy, other factors such as acceleration due to pressure grad
ients or other body forces can also affect the rate of entrainment. In this
paper, we develop a model for entrainment to explain the mechanism by whic
h buoyancy produces contrasting effects on entrainment in volumetrically he
ated flows in comparison to their unheated counterparts. The model highligh
ts the role of density stratification in the process of vortex sheet roll-u
p in free shear flows. With this model, we are also able to explain the hig
her entrainment of the plume relative to the unheated jet. The model is fur
ther extended to explain entrainment behavior during acceleration due to an
applied pressure gradient or other body forces. (C) 2000 American Institut
e of Physics. [S1070-6631(00)01408-2].