Applying early warning indicators to predict critical transitions in a lake undergoing multiple changes

Lakes are dynamic ecosystems that can transition among stable states. Since ecosystem‐scale transitions can be detrimental and difficult to reverse, being able to predict impending critical transitions in state variables has become a major area of research. However, not all transitions are detriment...

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Bibliographic Details
Published in:Ecological applications Vol. 32; no. 7; pp. e2685 - n/a
Main Authors: Rohde, Elizabeth, Pearce, Nolan J. T., Young, Joelle, Xenopoulos, Marguerite A.
Format: Journal Article
Language:English
Published: Hoboken, USA John Wiley & Sons, Inc 01-10-2022
Ecological Society of America
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Summary:Lakes are dynamic ecosystems that can transition among stable states. Since ecosystem‐scale transitions can be detrimental and difficult to reverse, being able to predict impending critical transitions in state variables has become a major area of research. However, not all transitions are detrimental, and there is considerable interest in better evaluating the success of management interventions to support adaptive management strategies. Here, we retrospectively evaluated the agreement between time series statistics (i.e., standard deviation, autocorrelation, skewness, and kurtosis—also known as early warning indicators) and breakpoints in state variables in a lake (Lake Simcoe, Ontario, Canada) that has improved from a state of eutrophication. Long‐term (1980 to 2019) monitoring data collected fortnightly throughout the ice‐free season were used to evaluate historical changes in 15 state variables (e.g., dissolved organic carbon, phosphorus, chlorophyll a) and multivariate‐derived time series at three monitoring stations (shallow, middepth, deep) in Lake Simcoe. Time series results from the two deep‐water stations indicate that over this period Lake Simcoe transitioned from an algal‐dominated state toward a state with increased water clarity (i.e., Secchi disk depth) and silica and lower nutrient and chlorophyll a concentrations, which coincided with both substantial management intervention and the establishment of invasive species (e.g., Dreissenid mussels). Consistent with improvement, Secchi depth at the deep‐water stations demonstrated expected trends in statistical indicators prior to identified breakpoints, whereas total phosphorus and chlorophyll a revealed more nuanced patterns. Overall, state variables were largely found to yield inconsistent trends in statistical indicators, so many breakpoints were likely not reflective of traditional bifurcation critical transitions. Nevertheless, statistical indicators of state variable time series may be a valuable tool for the adaptive management and long‐term monitoring of lake ecosystems, but we call for more research within the domain of early warning indicators to establish a better understanding of state variable behavior prior to lake changes.
Bibliography:Funding information
Canada Research Chairs; Natural Sciences and Engineering Research Council of Canada
Funding information Canada Research Chairs; Natural Sciences and Engineering Research Council of Canada
Handling Editor: Christer Nilsson
ISSN:1051-0761
1939-5582
DOI:10.1002/eap.2685