The dynamics of the mixed layer in the presence of an embedded geostro
phic jet has been investigated using a simple 1 1/2-layer model and a
two-dimensional primitive equation model. The jet vorticity induces a
spatial variability of the wind-driven inertial motions that can have
some important consequences on the mixed-layer dynamics. With a steady
wind stress parallel to the front. the main effect is the generation
of steady upwellings and downwellings due to the divergence of the mea
n Ekman drift (as reported by Niiler). With a cross-front wind, howeve
r, a dramatic exponential amplification of the inertial oscillations c
aused by an inertial resonance mechanism is found: this mechanism can
increase the inertial waves amplitude by a factor up to 10 within ten
inertial periods. Competition between this resonance mechanism and the
dispersion mechanisms (mainly the horizontal and vertical propagation
of inertial waves) that can limit its effects has been assessed. A co
nsequence of horizontal propagation is that energetic waves can propag
ate well away from the jet while continuing to absorb energy from the
wind. Downward propagation disperses this energy to a depth of at leas
t 500 m in a few days.