Inverse Estuaries in West Africa: Evidence of the Rainfall Recovery?

Luc Descroix,Victor Mendy,Bamol Ali Sow,Alexandre Badiane,Marie-Jeanne Senghor,Bakary Faty,Arame Dièye,Boubacar Demba Ba,Djiby Sow,Mamadou Thior,Yancouba Sané,Saloum Coly,Jean-Pierre Montoroi,Sylvie-Paméla Manga,Awa Diop,Julien Andrieu,Safietou Soumaré,Joseph Mingou,Éric Machu ,Yasmin Bouaïta ,Ange Bouramanding Diedhiou ,Jean‐Pierre Vandervaere

doi:10.3390/w12030647

Abstract

In West Africa, as in many other estuaries, enormous volumes of marine water are entering the continent. Fresh water discharge is very low, and it is commonly strongly linked to rainfall level. Some of these estuaries are inverse estuaries. During the Great Sahelian Drought (1968–1993), their hyperhaline feature was exacerbated. This paper aims to describe the evolution of the two main West African inverse estuaries, those of the Saloum River and the Casamance River, since the end of the drought. Water salinity measurements were carried out over three to five years according to the sites in order to document this evolution and to compare data with the historical ones collected during the long dry period at the end of 20th century. The results show that in both estuaries, the mean water salinity values have markedly decreased since the end of the drought. However, the Saloum estuary remains a totally inverse estuary, while for the Casamance River, the estuarine turbidity maximum (ETM) is the location of the salinity maximum, and it moves according to the seasons from a location 1–10 km downwards from the upstream estuary entry, during the dry season, to a location 40–70 km downwards from this point, during the rainy season. These observations fit with the functioning of the mangrove, the West African mangrove being among the few in the world that are markedly increasing since the beginning of the 1990s and the end of the dry period, as mangrove growth is favored by the relative salinity reduction. Finally, one of the inverse estuary behavior factors is the low fresh water incoming from the continent. The small area of the Casamance and Saloum basins (20,150 and 26,500 km² respectively) is to be compared with the basins of their two main neighbor basins, the Gambia River and the Senegal River, which provide significant fresh water discharge to their estuary.

Highlights

Alexandre Badiane 1,2,3, Marie-Jeanne Senghor 2, Ange-Bouramanding Diedhiou 2, Djiby Sow 2,3, Yasmin Bouaita 2, Safietou Soumaré 2,6,7, Awa Diop 2,8, Bakary Faty 9, Bamol Ali Sow 3,5, Eric Machu 5,10, Jean-Pierre Montoroi, Julien Andrieu 2,7 and Jean-Pierre Vandervaere
This study proposes to describe the current behavior of two West African inverse estuaries and to compare it with that observed during the Sahelian dry period of the end of the 20th century
A settled ensemble of five multi-sensor devices localized in the Casamance River estuary only, since Jan 2014; These devices are CTD sensors (Conductivity, Temperature, Depth) model Decagon© CTD 10 (Pullman, WA, the USA), each one was coupled with a Decagon© EM50 data logger

Summary

Introduction

Alexandre Badiane 1,2,3 , Marie-Jeanne Senghor 2 , Ange-Bouramanding Diedhiou 2 , Djiby Sow 2,3 , Yasmin Bouaita 2 , Safietou Soumaré 2,6,7 , Awa Diop 2,8 , Bakary Faty 9 , Bamol Ali Sow 3,5 , Eric Machu 5,10 , Jean-Pierre Montoroi 11 , Julien Andrieu 2,7 and Jean-Pierre Vandervaere 12. Fresh water discharge is very low, and it is commonly strongly linked to rainfall level. Some of these estuaries are inverse estuaries. West African inverse estuaries, those of the Saloum River and the Casamance River, since the end of the drought. The results show that in both estuaries, the mean water salinity values have markedly decreased since the end of the drought. The Saloum estuary remains a totally inverse estuary, while for the Casamance River, the estuarine turbidity maximum (ETM) is the location of the salinity maximum, and it moves according to the seasons from a location

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Conclusion