Abstract:Anthropogenic and climatic stressors on freshwater ecosystems are of global concern. However, the interactions and effects of multiple stressors (e.g., nutrient enrichment, climate warming, altered wind and precipitation) acting over different spatial and temporal scales are often complex and remain controversial. Here, we reconstructed one‐century dynamics of eutrophication and primary producer communities in algal‐dominated and macrophyte‐dominated zones of a large shallow lake (Taihu, China), by integrating… Show more
“…On the other hand, reduced erosion could increase water transparency and enhance light penetration in the water column by decreasing inputs of suspended particulate matter (Lischke et al, 2014), which is in agreement with the remarkable increase in our pigment‐based UVR index after 2000 (Figure 3e). This result indicates better light conditions and increased underwater light penetration availability (Leavitt et al, 1997; Lin et al, 2021), which would provide a suitable abiotic environment for the photosynthesis of planktonic algae and an extensive habitat for benthic algae. Thus, all of these lines of evidence characterise long‐term decreases in the trophic state and an increase in the light availability of BLC Lake.…”
Section: Discussionmentioning
confidence: 98%
“…Competitive interactions among algal communities also modulate their composition and structure (Ewing et al, 2020). Percentage shifts in different pigment concentrations can reflect variations in the algal community structure (Lin et al, 2021; McGowan, 2013). The increased abundance of siliceous algae and cyanobacteria compared to green algae (chlorophytes) indicates a shift in the algal community towards the dominance of siliceous algae during the past 20 years (Figure 4g).…”
Climate change and anthropogenic activities mutually degraded global lake ecosystems during the Anthropocene. Nutrient mitigation via catchment management has been a constant priority for lake ecological restoration; however, the outcomes after mitigation remain uncertain. In particular, there is limited knowledge on the effects of large‐scale forest restoration and soil erosion reduction in catchments on the ecological dynamics of downstream aquatic systems.
Here, we study a strategically chosen alpine lake from the Loess Plateau in northern China, which has been extensively afforested in the past decades. We present high‐resolution, multi‐proxy records to reconstruct environmental and ecological dynamics since 1960. To quantify the potential mechanisms, we combined evidence from palaeolimnological records, contemporary field observations and process‐based ecosystem modelling. We developed palaeorecord‐based proxies for water transparency, nutrient concentrations and algal composition, and applied these proxies to ecosystem modelling.
Our results show that despite the concurrent decline in nutrient levels, the lake ecosystem has experienced large‐magnitude rapid shifts since 2000, characterised by unambiguously increased algae proliferation and community changes. The modelling results revealed that the reduction in soil erosion acts as a “double‐edged sword”; that is, lower external nutrient loading via soil erosion is ideal for in‐lake algae inhibition, whereas increasing light availability counteracts the reduced yet still sufficient nutrient concentrations and, ultimately, promotes temporary algal proliferation via extended habitats and intensive photosynthesis. Intriguingly, lake warming plays a secondary role in driving these ecological dynamics.
Our results emphasised the unexpected algal proliferation when the nutrient level declined in lake ecosystems; thus, other compound factors, including water transparency and climate warming, need to be incorporated for reliable prediction and effective restoration. A multi‐disciplinary approach integrating palaeorecords as ecological indicators and process‐based ecosystem modelling holds great potential for investigating long‐term lake ecological dynamics in the context of rapid global changes.
“…On the other hand, reduced erosion could increase water transparency and enhance light penetration in the water column by decreasing inputs of suspended particulate matter (Lischke et al, 2014), which is in agreement with the remarkable increase in our pigment‐based UVR index after 2000 (Figure 3e). This result indicates better light conditions and increased underwater light penetration availability (Leavitt et al, 1997; Lin et al, 2021), which would provide a suitable abiotic environment for the photosynthesis of planktonic algae and an extensive habitat for benthic algae. Thus, all of these lines of evidence characterise long‐term decreases in the trophic state and an increase in the light availability of BLC Lake.…”
Section: Discussionmentioning
confidence: 98%
“…Competitive interactions among algal communities also modulate their composition and structure (Ewing et al, 2020). Percentage shifts in different pigment concentrations can reflect variations in the algal community structure (Lin et al, 2021; McGowan, 2013). The increased abundance of siliceous algae and cyanobacteria compared to green algae (chlorophytes) indicates a shift in the algal community towards the dominance of siliceous algae during the past 20 years (Figure 4g).…”
Climate change and anthropogenic activities mutually degraded global lake ecosystems during the Anthropocene. Nutrient mitigation via catchment management has been a constant priority for lake ecological restoration; however, the outcomes after mitigation remain uncertain. In particular, there is limited knowledge on the effects of large‐scale forest restoration and soil erosion reduction in catchments on the ecological dynamics of downstream aquatic systems.
Here, we study a strategically chosen alpine lake from the Loess Plateau in northern China, which has been extensively afforested in the past decades. We present high‐resolution, multi‐proxy records to reconstruct environmental and ecological dynamics since 1960. To quantify the potential mechanisms, we combined evidence from palaeolimnological records, contemporary field observations and process‐based ecosystem modelling. We developed palaeorecord‐based proxies for water transparency, nutrient concentrations and algal composition, and applied these proxies to ecosystem modelling.
Our results show that despite the concurrent decline in nutrient levels, the lake ecosystem has experienced large‐magnitude rapid shifts since 2000, characterised by unambiguously increased algae proliferation and community changes. The modelling results revealed that the reduction in soil erosion acts as a “double‐edged sword”; that is, lower external nutrient loading via soil erosion is ideal for in‐lake algae inhibition, whereas increasing light availability counteracts the reduced yet still sufficient nutrient concentrations and, ultimately, promotes temporary algal proliferation via extended habitats and intensive photosynthesis. Intriguingly, lake warming plays a secondary role in driving these ecological dynamics.
Our results emphasised the unexpected algal proliferation when the nutrient level declined in lake ecosystems; thus, other compound factors, including water transparency and climate warming, need to be incorporated for reliable prediction and effective restoration. A multi‐disciplinary approach integrating palaeorecords as ecological indicators and process‐based ecosystem modelling holds great potential for investigating long‐term lake ecological dynamics in the context of rapid global changes.
“…It has also been proven through global research reports that among the various impacts of climatic change, the relationships between the abiotic factors such as turbidity or total solids and the production characteristics of bacterial and viral populations are quite significant. Increases in the total solids concentrations through cultural eutrophication have a direct bearing on biotic survival in shallow and urban lake environments (Lin et al 2021 ). Fig.…”
Section: Factors Influencing the Lake Properties Under A Pandemic Sce...mentioning
A wide spectrum of algal–bacterial-viral relationships in aquatic ecosystems provide a complex matrix of interactions with abiotic factors such as temperature, pH and total solids concentrations in water. These relationships are quite reflective of the summative status of changes undergone by the lacustrine environments. However, the environmental risks and vulnerability of aquatic ecosystems in the regions of Global South including India, owing to the increase in sewage and domestic discharges with high loads of viral particles in the post-COVID-19 times have only been sparsely reported. Collective scenarios emerging from the influential factors such as the increase in salinity and total solids need to be explored for scientific significance and understanding. The present article opines that while the changes in the biotic and abiotic factors can enhance or alleviate these risks, identification of the stable and alternate states of the ecosystems make excellent ecosystem level proxies for pandemic-related disturbances at a macro-scale. Further, the need to plan Nature based Solutions to counter these risks under pandemic-like scenarios is discussed.
“…In addition to anthropogenic stressors, interannual water-level fluctuations are driven by changes in climate variability throughout North America (Adrian et al, 2009;Havens & Jeppesen, 2018), particularly in arid regions where evaporation exceeds precipitation (Xiao et al, 2018). Furthermore, synergistic interactions between anthropogenic eutrophication, lake warming, and altered precipitation can stimulate excessive algal blooms during the summer months, leading to unprecedented changes in lake structure and function (Lin et al, 2021;Paerl & Huisman, 2008). Shallow lakes often exhibit two alternate states: a clear water state with abundant macrophytes, and a turbid, phytoplankton-rich state (Bayley et al, 2007;Scheffer et al, 1993).…”
The timing and causes of lake eutrophication are often obscured when multiple anthropogenic disturbances coincide in space and time. This issue is particularly problematic for shallow lakes in arid regions that experience strong climatic forcing which alters lake hydrology and water levels, and further conflates causal drivers.
We used Utah Lake (Utah, U.S.A.) as a model system to examine how natural hydrological variability and anthropogenic forcing influence ecosystem structure of large shallow lakes in arid climates. Paleolimnological analyses of sedimentary biogeochemistry, pigments, DNA, and morphological fossils were used to identify shifts in primary production and evaluate the relative influence of regional climate‐driven hydrological variability and of humans on ecosystem structure.
Sediment cores revealed that the phase prior to non‐indigenous settlement included numerous macrophyte and gastropod remains, sedimentary DNA from plants, low organic matter, and low algal production. An abrupt transition occurred in the late 19th century concomitant with agricultural and urban expansion and the introduction of common carp, which was characterised by a loss of macrophytes and an increase in phytoplankton abundance as indicated by sedimentary DNA and pigment concentrations. A further shift to increased cyanobacteria occurred c. 1950 when exponential population growth increased wastewater influx, as recorded by sedimentary δ15N values.
Taken together, our data demonstrate that the current eutrophic state of Utah Lake is a function of anthropogenic forcing rather than natural climate‐driven hydrological fluctuations. Furthermore, large lakes in arid regions can exhibit similar patterns of abrupt ecosystem change between alternate states as those observed in northern temperate/boreal and subtropical ecosystems.
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