Pe. Holloway et al., A NONLINEAR MODEL OF INTERNAL TIDE TRANSFORMATION ON THE AUSTRALIAN NORTH-WEST SHELF, Journal of physical oceanography, 27(6), 1997, pp. 871-896
A numerical solution to the generalized Korteweg-de Vries (K-dV) equat
ion, including horizontal variability and dissipation, is used to mode
l the evolution of an initially sinusoidal long internal wave, represe
nting an internal tide. The model shows the development of the wavefor
m to the formation of shocks and solitons as it propagates shoreward o
ver the continental slope and shelf. The model is run using observed h
ydrographic conditions from the Australian North West Shelf and result
s are compared to current meter and thermistor observations from the s
helf-break region. It is found from observations that the coefficient
of nonlinearity in the K-dV equation changes sign from negative in dee
p water to positive in Shallow water, and this plays a major role in d
etermining the form of the internal tide transformation. On the shelf
there is strong temporal variability in the nonlinear coefficient due
to both background shear flow and the large amplitude of the internal
tide, which distorts the density profile over a wave period. Both the
model and observations show the formation of an initial shock on the l
eading face of the internal tide. In shallow water, the change in sign
of the coefficient of nonlinearity causes the shock to evolve into a
tail of short period sinusoidal waves. After further propagation a sec
ond shock forms on the back face of the wave, followed by a packet of
solitons. The inclusion of bottom friction in the model is investigate
d along with the dependance on initial wave amplitude and variability
in the coefficients of nonlinearity and dispersion. Friction is found
to be important in limiting the amplitudes of the evolving waves.