Yz. You, SALINITY VARIABILITY AND ITS ROLE IN THE BARRIER-LAYER FORMATION DURING TOGA-COARE, Journal of physical oceanography, 25(11), 1995, pp. 2778-2807
During the intensive observation period of TOGA-COARE between November
1992 and February 1993, two R/V Franklin cruises, FR09/92 and FR01/93
, were carried out to study the response of oceanic surface layer temp
erature and salinity to atmospheric inputs such as wind, radiation, pr
ecipitation, etc. A total of seven Seasoar surveys (each has a square
of about 50 km) were designed and performed to monitor the variations
in oceanic heat and freshwater content. This paper focuses on the obse
rved salinity variation in spatial and time scales and its association
with the barrier layer production. During the first and second 1992 s
urveys, a salinity front was observed. The crossing-front salinity dif
ference was at least 0.16 from the surface down to below 40 m, implyin
g a freshwater influx of about 20 cm. MIT Doppler radar located on R/V
Vickers showed very heavy and persistent storm rains covered a very l
arge area of a few hundred square kilometers west of the surveys for t
wo days before the surveys started, giving a possible source of that m
uch freshwater intake by the ocean. The low salinity water pool formed
by the storm rains then moved eastward under a relatively weak wester
ly wind and a wide eastward ocean current. The salinity front of the p
ool was observed during the first survey and again observed during the
second survey, which was estimated to travel in the southeast directi
on with a speed of 20 cm s(-1). ADCP shear data show an eastward flow
in the top 40 m of the front but a reverse flow in the bottom of the f
ront, suggesting that the strong salinity stratification in the lower
isothermal layer is most likely caused by the shears. It is this eastw
ard-moving low salinity water in the upper level of the front over the
high salinity water moving westward in the bottom of the front that i
s responsible for the production an observed barrier layer at least 30
m thick, in which salinity changed 0.2-0.3 in the vertical, while ver
tical temperature changed only 0.1 degrees-0.2 degrees C for the same
depth range. However, the situation was very different during one of t
he 1993 surveys, on which occasion the westerly wind was stronger with
a speed of 15 knots on average and the rain-formed low salinity water
pools penetrated deeply. Between the bottom of the pools and of the i
sothermal layer there was a strong salinity stratified layer with a ve
rtical salinity change of 0.1-0.15 and a vertical temperature change o
f 0.1 degrees C. A barrier layer about 10 m thick was formed. This giv
es an example that direct rainfall under strong wind forcing can also
generate a barrier layer, but one much thinner than the one produced b
y advection. The reason is probably that with an existing mixed layer,
rain showers coming into the surface can easily reach the bottom of a
mixed layer under turbulent mixing and entrainment, while the thickne
ss of a barrier layer is proportional to the amount of rain input.