Abstract
Land use and climate change are anticipated to affect phytoplankton of lakes worldwide. The effects will depend on the magnitude of projected land use and climate changes and lake sensitivity to these factors. We used random forests fit with long-term (1971-2016) phytoplankton and cyanobacteria abundance time series, climate observations (1971-2016), and upstream catchment land use (global Clumondo models for the year 2000) data from 14 European and 15North American lakes basins. We projected future phytoplankton and cyanobacteria abundance in the 29 focal lake basins and 1567lakes across focal regions based on three land use (sustainability, middle of the road, and regional rivalry) and two climate (RCP 2.6 and 8.5) scenarios to mid-21st century. On average, lakes are expected to have higher phytoplankton and cyanobacteria due to increases in both urban land use and temperature, and decreases in forest habitat. However, the relative importance of land use and climate effects varied substantially among regions and lakes. Accounting for land use and climate changes in a combined way based on extensive data allowed us to identify urbanization as the major driver of phytoplankton development in lakes located in urban areas, and climate as major driver in lakes located in remote areas where past and future land use changes were minimal. For approximately one-third of the studied lakes, both drivers were relatively important. The results of this large scale study suggest the best approaches for mitigating the effects of human activity on lake phytoplankton and cyanobacteria will depend strongly on lake sensitivity to long-term change and the magnitude of projected land use and climate changes at a given location. Our quantitative analyses suggest local management measures should focus on retaining nutrients in urban landscapes to prevent nutrient pollution from exacerbating ongoing changes to lake ecosystems from climate change.
Highlights
Lakes across the globe are threatened by multiple stressors (Vörösmarty et al, 2010)
Synthèse et d'Analyse sur la Biodiversité; Vermont Water Resources and Lake Studies Center, Grant/Award Number: G16AP00087; IGB long-term ecological research programme climate changes in a combined way based on extensive data allowed us to identify urbanization as the major driver of phytoplankton development in lakes located in urban areas, and climate as major driver in lakes located in remote areas where past and future land use changes were minimal
We expected an increase in phytoplankton and cyanobacteria abundances under both the best-and worst-case climate and land use scenarios, mainly because temperature and urban areas are projected to increase in the future
Summary
Lakes across the globe are threatened by multiple stressors (Vörösmarty et al, 2010). Recent developments including the Clumondo global land use models (Van Asselen & Verburg, 2013) and ISIMIP2b global time-series climate model data (Frieler et al, 2017; https://www.isimip.org/protocol/#isimip2b) allow such projections worldwide (e.g., Woolway & Merchant, 2019). These new model output data provide opportunities to disentangle and explore the combined effects of projected land use and climate changes on lake ecosystems. We expected an increase in phytoplankton and cyanobacteria abundances under both the best-and worst-case climate and land use scenarios, mainly because temperature and urban areas are projected to increase in the future. | 3 of the scope of lake phytoplankton changes under projected future environmental conditions with implications for lake ecosystem services and management priorities
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