Vertical profiles of the time-averaged wind stress, wind speed and buoyancy
flux from the off-shore tower site in the Riso Air Sea Experiment are used
to evaluate similarity theory in the coastal zone. The observed dependence
of the non-dimensional wind shear on stability is compared to the traditio
nal parametrization. Relationships between the non-dimensional shear, devel
opment of internal boundary layers and wave state are explored.
We find that the largest-scale turbulent eddies are suppressed in shallow c
onvective internal boundary layers, leading to larger non-dimensional shear
than that of the traditional prediction based only on stability. In shallo
w stable boundary layers, elevated generation of turbulence leads to smalle
r non-dimensional shear compared to the traditional prediction. Over young
growing waves in stable stratification, the observed non-dimensional shear
is less than that over older more mature waves in otherwise similar conditi
ons. The non-dimensional shear is a function of wave state for stable condi
tions even though the observations are well above the wave boundary layer.
We conclude that development of shallow internal boundary layers and young
growing-wave fields, both of which are common in the coastal zone, can lead
to substantial departures of the non-dimensional shear from the prediction
based only on stability.