Add to ORKGMonitoring lakes in high-latitude areas can provide a better understanding of freshwater systems sensitivity and accrete knowledge on climate change impacts. Phytoplankton are sensitive to various conditions: warmer temperatures, earlier ice-melt and changing nutrient sources. While satellite imagery can monitor phytoplankton biomass using chlorophyll a (Chl) as a proxy over large areas, detection of Chl in small lakes is hindered by the low spatial resolution of conventional ocean color satellites. The short time-series of the newest generation of space-borne sensors (e.g., Sentinel-2) is a bottleneck for assessing long-term trends. Although previous studies have evaluated the use of high-resolution sensors for assessing lakes’ Chl, ...
Phytoplankton biomass is important to monitor in lakes due to its influence on water quality and lak...
Small inland waters (SIWs) – waterbodies smaller than 100 km2 – are the predominant form of lakes gl...
The concentration of chlorophyll a (chl a; as a proxy for phytoplankton biomass) provides an indicat...
Monitoring lakes in high-latitude areas can provide a better understanding of freshwater systems sen...
Monitoring temporal changes in phytoplankton dynamics in high latitude lakes is particularly timely ...
The frequency, intensity, and geographical distribution of harmful phytoplankton blooms are on the r...
We estimated chlorophyll-a (Chl-a) concentration using various combinations of routine sampling, aut...
Eutrophication of inland waters is an environmental issue that is becoming more common with climatic...
Freshwater ecosystems are challenged by cultural eutrophication across the globe, and it is a priori...
A new method was developed, evaluated, and applied to generate a global dataset of growing-season ch...
Directives and legislations worldwide aim at representatively and continuously monitoring the ecolog...
Under the current high anthropic pressure and climate change scenarios, a trend towards increasing c...
Lakes are key indicators of environmental change and major repositories of biodiversity and ecosyste...
Ecologists collectively predict that climate change will enhance phytoplankton biomass in northern l...
Phytoplankton biomass is important to monitor in lakes due to its influence on water quality and lak...
Small inland waters (SIWs) – waterbodies smaller than 100 km2 – are the predominant form of lakes gl...
The concentration of chlorophyll a (chl a; as a proxy for phytoplankton biomass) provides an indicat...
Monitoring lakes in high-latitude areas can provide a better understanding of freshwater systems sen...
Monitoring temporal changes in phytoplankton dynamics in high latitude lakes is particularly timely ...
The frequency, intensity, and geographical distribution of harmful phytoplankton blooms are on the r...
We estimated chlorophyll-a (Chl-a) concentration using various combinations of routine sampling, aut...
Eutrophication of inland waters is an environmental issue that is becoming more common with climatic...
Freshwater ecosystems are challenged by cultural eutrophication across the globe, and it is a priori...
A new method was developed, evaluated, and applied to generate a global dataset of growing-season ch...
Directives and legislations worldwide aim at representatively and continuously monitoring the ecolog...
Under the current high anthropic pressure and climate change scenarios, a trend towards increasing c...
Lakes are key indicators of environmental change and major repositories of biodiversity and ecosyste...
Ecologists collectively predict that climate change will enhance phytoplankton biomass in northern l...
Phytoplankton biomass is important to monitor in lakes due to its influence on water quality and lak...
Small inland waters (SIWs) – waterbodies smaller than 100 km2 – are the predominant form of lakes gl...
The concentration of chlorophyll a (chl a; as a proxy for phytoplankton biomass) provides an indicat...