Your search keyword '"water renewal time"' showing total 2 results

1. Modelling the water dynamics of a tidal lagoon: The impact of human intervention in the Nador Lagoon (Morocco)

Author

Benyounes Abdellaoui, Marco Bajo, Georg Umgiesser, Karim Hilmi, and Francesco Maicu

Subjects

geography, geography.geographical_feature_category, Baroclinity, Climate change, Geology, Aquatic Science, Oceanography, Inlet, Salinity, Water dynamics, Climate change scenario, Environmental science, Dominance (ecology), Tidal prism

Abstract

The Lagoon of Nador (Morocco) has been subject to relevant man-made changes in recent years, which consisted of closing the inlet and opening a new one, wider and deeper, with long lateral jetties. In this paper, we study some of the consequences of this modification, using a 3D hydrodynamic model that allows a comparison of the two configurations (old and new inlet). This would be not possible analysing only the observations and the approach we followed is a general method that can be applied wherever man-made or natural changes affect a coastal system. We have created two numerical grids, one with the old inlet and one with the new inlet, both covering the entire lagoon and a wide part of the coastal area. Using these two configurations, fully baroclinic simulations were run for one year. The results show a significant increase of the tidal amplitude and of the water circulation inside the lagoon, with a tidal prism four times larger. The change of the tidal asymmetry from positive to negative values (−0.7 in the inlet) causes a shift toward the ebb dominance, with implications for the mid-term morphological evolution. With the new inlet the water renewal time of the lagoon decreased from 57 to 15 days and the water temperature got warmer in winter (+1 °C) and colder in summer (−2 °C). As a consequence of this, the evaporation lowered and the salinity reduced by 0.8 PSU. The seasonal variability of the water renewal time shows that the tidal forcing, the baroclinic circulation and the wind contribute to the mixing processes. The mixing capacity of the lagoon (0.7) did not change because it is an intrinsic property of the lagoon morphology and of the atmospheric forcing. Finally, we found that the change of the water renewal time, with the new inlet, is higher than the change predicted, with the old inlet, under the RCP8.5 climate change scenario.

Published

2021

2. Frontal eddies along a western boundary current

Author

Joachim Ribbe, Jörg-Olaf Wolff, Mochamad Furqon Azis Ismail, and Liv Toaspern

Subjects

0106 biological sciences, Rotation period, Chlorophyll a, 010504 meteorology & atmospheric sciences, 010604 marine biology & hydrobiology, Geology, Subtropics, Aquatic Science, Oceanography, 01 natural sciences, Boundary current, Sea surface temperature, chemistry.chemical_compound, Drifter, chemistry, Eddy, Primary productivity, 0105 earth and related environmental sciences

Abstract

Cyclonic frontal eddies are distinguishable from the surrounding water due to their unique biological and physical characteristics and have been observed in all western boundary current regions. These eddies spawn from cut-off meanders and are found on the landward side of the current. Here, we report for the first time observed frontal eddies for the intensification zone (north of 28°S) of the East Australian Current (EAC) off Southeast Queensland, Australia, by analysing remotely sensed sea surface temperature (SST) and chlorophyll-a (Chl-a) data. The frontal eddies were detected initially in the analysis of satellite tracked surface drifters. The shelf-crossing cyclonic drifter pathways indicated the presence of drifter-trapping cyclonic frontal eddies. The subsequent analysis of satellite images allows to quantify key eddy characteristics, cross-shelf volume transports associated with eddy filaments, eddy-driven shelf water renewal time scales, and export of total Chl-a and carbon per day. The observed frontal eddies have core radii of approximately 13 km and 15 km. The cold core surface SST anomaly and elevated chl-a indicates eddy entrainment of shelf water. The translational or core displacement velocity is estimated with 0.17 m s−1 or 15 km per day and the tangential velocity quantified from tracking surface drifters is 0.28 m s−1 to − 0.5 m s−1. This results in a rotational period of 1.9 days to 3.9 days. We use maximum Chl-a and SST gradients to approximate the width of importing and exporting filaments associated with the frontal eddy to derive volume transports of 1.5 Sv and 1.9 Sv (import) and 0.3 Sv and 1.8 Sv (export), respectively. Chl-a concentrations of the exporting filaments are about 0.4 mg m−3 to 0.6 mg m−3 yielding a total export of 13–78 t of Chl-a per day. The frontal eddy induced on-shelf transport of 130 km3–160 km3 per day represents between 18% and 22% of the shelf volume. Therefore, it would take approximately five days to renew all shelf water. We conclude that the observed frontal eddies of the northern intensification zone of the EAC potentially play an important role in determining cross-shelf exchanges, contribute to on-shelf marine conditions, enhancing coastal primary productivity and are possibly important to the export of shelf water properties such as the fish larvae of subtropical species via entrainment.

Published

2018