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and unbalance the water bodies (Becerra-Jurado et al., 2012).

      1.12.4 Burrowing Animals

      1.12.5 Algal Blooms

      In open water systems such as FSF-CWs, nutrients (N and P) favour the over-development of algae and cyanobacteria in spring and summer. When starving on nutrients, cyanobacteria can die explosively, releasing various kinds of toxins (neurotoxins, cytotoxins, endotoxins, or hepatotoxins), collectively known as cyanotoxins. The relations between nutrients feeding in function of hydrologic conditions (storm and non-storm) and cyanobacteria death are still delicate to understand (Hartshorn et al., 2016). Indeed, proliferation of toxin-producing cyanobacterial blooms is attributed to a large number of environmental factors, including: unbalanced N and P inputs (leading to silicate starvation and the disappearance of diatoms with siliceous frustules); increased temperature, water residence times, vertical stratification, and pH. All of this will be exacerbated by climate change (Howard et al., 2017). The toxin releases pose a danger to humans and animals, in the wetland themselves as well as in the water bodies downstream (Griffiths and Mitsch, 2020).

      1.13.1 Monitoring Large-Scale CWs

Photographs of (a) the 2-ha FSF-CW (b) the UAV Spyboat, collecting samples and monitoring dissolved oxygen and temperature.

      1.13.2 Vegetation Monitoring

      Aquatic plants are an essential element of CW but the monitoring of their development (e.g., growth, senescence) is not easy, especially on large-scale systems. Accurate field surveys can be organized from the ground but there are time-consuming and labour-intensive. Very large systems cannot be monitored completely. Depending upon the water depth, some areas might not be accessible by boat. Recent progress in aerial imagery by UAS (i.e., aerial) can be a solution to these problems. UAS can be fitted with classical RGB cameras as well as more sophisticated sensors to cover the light spectrum down to NIR: they can detect free water areas, emerged as well as submerged aquatic plants (Chabot et al., 2017; Chabot et al., 2018). After calibration with ground sensors, an estimation of dissolved oxygen, turbidity (Wang et al., 2020a) or Chlorophyll-a (Gitelson et al., 2007) can also be provided. However, dedicated flights should be organized with licensed UAS pilots and under proper weather conditions (no rain and low wind). Furthermore, wildlife disturbance and even collisions with birds should be considered (Jarrett et al., 2020). Satellite images can also be used even if the spatial resolution is lower.

      Saberioon et al. (2020) have successfully monitored Chlorophyll-a and total suspended solids in fishponds and sandpit lakes of various surfaces (tens to hundreds of hectares) and depths (from 2 m for fishponds to 10 m for sandpit lakes) using the Sentinel-2 constellation. The two Sentinel-2 satellites are working at high spatial resolution (10 to 60 m) with a revisit cycle of 5 days. Sentinel-2 satellites are fitted with a multi-spectral imager working with 13 bands (from visible to mid-infra-red) and provide a high temporal resolution series of images, if the sky is cloud-free (Saberioon et al., 2020). These images are freely available on the Copernicus-ESA website (https://scihub.copernicus.eu/).

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