Asymmetric tidal straining across an inlet: Lateral inversion and variability over a tidal cycle

Tidal straining is a phenomenon of temporal variations in stratification and mixing resulting from the interaction of a longitudinal salinity gradient with the vertical shear of the horizontal tidal velocity. As a result, the theory predicts stronger and weaker stratification during ebb/low tide and flood/high tide, respectively. In contrast to this well-known temporal asymmetry, in this study, we document in situ measurements demonstrating a lateral asymmetry and lateral inversion of tidal straining at Barataria Pass, a narrow (∼600 m wide) tidal inlet of Barataria Bay in southeastern Louisiana. During flood, the eastern side of the channel had strong stratification of 4 PSU salinity change over a 1.5 m thin layer while the western side had a 2 PSU change over a 12 m water column. This strong lateral difference decreased as flood continued until near the end of the flood when it reached vertically well-mixed condition across the channel. During ebb it was just the opposite such that the western side became stratified while the eastern end was well-mixed. This resulted to a small correlation coefficient of −0.05 for stratification between the west and east sides, although the central channel and east side have a high correlation coefficient of 0.88. The tidally averaged salinity was higher on the western end than the eastern end except in a narrow boundary layer close to the eastern shore. This is an apparent contradiction to what the Coriolis effect would produce in classical estuarine dynamics. Our hypothesis for the observed difference arises from the influence of the river water coming out of the Mississippi River through the Southwest Pass of the Birdfoot Delta. This water mass may have played a role in the observed, complicated lateral inversion of the tidal straining. This study underlines the complexity of estuarine dynamics proximal to large deltaic systems and we anticipate that these results will underscore the need for a modeling study to further investigate this dynamic process.