Abstract
Extreme weather events (EWEs) represent meteorological hazards for coastal lagoon hydrodynamics, of which intensity and frequency are increasing over the last decades as a consequence of climate changes. The imbalances they generated should affect primarily vulnerable low-lying areas while potentially disturbing the physical balances (salt and water temperature) and, therefore, the ecosystem equilibrium. This study arises from the need to assess the impact of EWEs on the Ria de Aveiro, a lagoon situated in the Portuguese coastal area. Furthermore, it was considered that those events occur under the frame of a future sea-level rise, as predicted by several climate change scenarios. Two EWEs scenarios, a dry and an extremely wet early summer reflecting past situations and likely to occur in the future, were considered to assess the departure from the system baseline functioning. It was used as a biogeochemistry model that simulates the hydrodynamics, as well as the baseline physical and biogeochemistry state variables. The dry summer scenario, corresponding to a significant reduction in the river’s inflow, evidences a shift of the system to a situation under oceanic dominance characterized by colder and saltier water (~18 °C; 34 PSU) than the baseline while lowering the concentration of the nutrients and reducing the phytoplankton population to a low-level limit. Under a wet summer scenario, the lagoon shifted to a brackish and warmer situation (~21 °C, <15 PSU) in a time scale of some tidal periods, driven by the combining effect of the tidal transport and the river’s inflow. Phytoplankton patterns respond to variability on local and short-term scales that reflect physical conditions within the lagoon, inducing nutrient-supported growth. Overall, the results indicate that EWEs generate local and transient changes in physical conditions (namely salinity and water temperature) in response to the characteristic variability of the lagoon’s hydrodynamics associated with a tidal-dominated system. Therefore, in addition to the potential impact of changing physical conditions on the ecosystem, saline intrusion along the lagoon or the transfer of brackish water to the mouth of the system are the main consequences of EWEs, while the main biogeochemistry changes tend to remain moderate.
Highlights
Extreme weather events (EWEs) are currently associated with climate changes and can be understood as extreme weather events that can manifest as maximum or minimum daily air temperature or precipitation
EWEs are very short-lasting phenomena, the of increase their frequency or inducing physical and biogeochemistry stresses and challenging the resilience intensity may durably change the physical conditions of natural coastal ecosystems, inof resident species
The study presented two scenarios representing extreme meteorological events in the Ria de Aveiro Lagoon coastal area, taking into account the sea-level rise predicted for the Portuguese coastal area
Summary
Extreme weather events (EWEs) are currently associated with climate changes and can be understood as extreme weather events that can manifest as maximum or minimum daily air temperature or precipitation. In this context, heatwaves, extreme dryness situations, storm surges, or high-amplitude ocean waves can be seen as EWE cases [1,2]. Report of the Intergovernmental Panel on Climate Change [8], the EWEs assessment has improved and is predicted to become more common in the future, following the global warming trend. Sea level on the Portuguese coast has been reported to have increased at a rate of 2.1 ± 0.1 mm/year, with an increase of
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