Abstract. Natural lakes and big artificial reservoirs can affect the weather regime of
surrounding areas but, usually, consideration of all aspects of this impact
and their quantification is a difficult task. The Alqueva reservoir, the largest
artificial lake in western Europe, located on the south-east of Portugal, was
filled in 2004. It is a large natural laboratory that allows the study of
changes in surface and in landscape and how they affect the weather in the
region. This paper is focused on a 3-day case study, 22–24 July 2014, during
which an intensive observation campaign was carried out. In order to quantify
the breeze effects induced by the Alqueva reservoir, two simulations with the
mesoscale atmospheric model Meso-NH coupled to the FLake freshwater lake model
has been performed. The difference between the two simulations lies in the
presence or absence of the reservoir on the model surface. Comparing the two
simulation datasets, with and without the reservoir, net results of the lake
impact were obtained. Magnitude of the impact on air temperature, relative
humidity, and other atmospheric variables are shown. The clear effect of a lake
breeze (5–7 m s−1) can be observed during daytime on distances up to
6 km away from the shores and up to 300 m above the surface. The lake breeze
system starts to form at 09:00 UTC and dissipates at 18:00–19:00 UTC with
the arrival of a larger-scale Atlantic breeze. The descending branch of the
lake breeze circulation brings dry air from higher atmospheric layers
(2–2.5 km) and redistributes it over the lake. It is also shown that
despite its significant intensity the effect is limited to a couple of
kilometres away from the lake borders.
Nowadays, the Mediterranean freshwater systems face the threat of water scarcity, along with multiple other stressors (e.g., organic and inorganic contamination, geomorphological alterations, invasive species), leading to the impairment of their ecosystem services. All these stressors have been speeding up, due to climate variability and land cover/ land use changes, turning them into a big challenge for the water management plans. The present study analyses the physicochemical and phytoplankton biomass (chlorophyll-a) dynamics of a large reservoir, in the Mediterranean region (Alqueva reservoir, Southern Portugal), under diverse meteorological conditions and land cover/land use real scenarios (2017 and 2018). The most important stressors were identified and the necessary tools and information for a more effective management plan were provided. Changes in these parameters were further related to the observed variations in the meteorological conditions and in the land cover/land use. The increase in nutrients and ions in the water column, and of potentially toxic metals in the sediment, were more obvious in periods of severe drought. Further, the enhancement of nutrients concentrations, potentially caused by the intensification of agricultural activities, may indicate an increased risk of water eutrophication. The results highlight that a holistic approach is essential for a better water resources management strategy.
Abstract. The Alqueva reservoir (southeast of Portugal) is the largest artificial lake in western Europe and a strategic freshwater supply in the region. The reservoir is of scientific interest in terms of monitoring and maintaining the quality and quantity of water and its impact on the regional climate. To support these tasks, we conducted numerical studies of the thermal and gas regimes in the lake over the period from May 2017 to March 2019, supplemented by the data observed at the weather stations and floating platforms during the field campaign of the ALentejo Observation and Prediction (ALOP) system project. The 1D model, LAKE 2.0, was used for the numerical studies. Since it is highly versatile and can be adjusted to the specific features of the reservoir, this model is capable of simulating its thermodynamic and biogeochemical characteristics. Profiles and time series of water temperature, sensible and latent heat fluxes, and concentrations of CO2 and O2 reproduced by the LAKE 2.0 model were validated against the observed data and were compared to the thermodynamic simulation results obtained with the freshwater lake (FLake) model. The results demonstrated that both models captured the seasonal variations in water surface temperature and the internal thermal structure of the Alqueva reservoir well. The LAKE 2.0 model showed slightly better results and satisfactorily captured the seasonal gas regime.
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