Salgado, J., C. D. Sayer, S. J. Brooks, T. A. Davidson, A. G. Baker, N. Willby, I. R. Patmore, B. Goldsmith, H. Bennion and B. Okamura (2019) Connectivity and zebra mussel invasion offer short‐term buffering of eutrophication impacts on floodplain lake landscape biodiversity. Diversity and Distribution. https://doi.org/10.1111/ddi.12938
Here is a short summary of the talk we gave yesterday, at the Aquatic biodiversity and ecosystems conference held at the University of Liverpool, where we asked the question: Does connectivity between lakes enhance biodiversity resilience to eutrophication in the Upper Lough Erne area and in The Broads? A talk based on the same research was delivered in Baltimore, USA for the 100th Annual Meeting of the Ecological Society of America – see this post.
Our data was a compilation of lake surveys in both lake districts and for two time periods: the 1980 and recent time (thanks you to all our partners who were willing to share their data, by the way!). Each lake survey comprises of:
- Extensive botanical work, recording aquatic plants from the open water and the marginal zone, and
- Collecting water samples that are later analysed in the lab for phytoplankton abundance, concentration of nutrients such as phosphorus and water chemistry in general.
Our data shows that nutrient pollution drives ecosystem functioning in both regions and during both time periods. This reminds us on the importance of good policies to protect freshwaters while maintaining thriving agriculture.
The situation with biodiversity is a bit different as it appears to be influenced both by the local conditions (lake size and shape, nutrients status) and landscape-wide connectivity. One main difference between the Upper Lough Erne lakes and the Broads is that flood connectivity in the Upper lough Erne is a major factor structuring in the aquatic plant communities there. Does this induce greater resilience? remains a pending question we are working on.
All these results are being written up into a scientific article, so please get in touch if you’d like to discuss or report them!
The eutrophication (or excessive enrichment by nutrients as a result of human activities) of lowland lakes is a widespread problem globally but is particularly serious in densely populated areas of Europe and North America.
While the negative effects of nutrient enrichment are considerable in term of biodiversity loss and alterations in ecosystem functioning, one possible positive aspect is the increased rate of organic carbon burial. This means that regional carbon budgets may benefit from eutrophication, leading to a positive effect on climate regulation.
The possible climate regulating role of lakes as carbon sinks is only now being evaluated but to date there has been limited consideration of change in organic carbon burial rates in response to eutrophication.
A recently published study by Helen Bennion, one of the Lake BESS team, with John Anderson (Loughborough University) and Andy Lotter (Utrecht University) has revealed that the accumulation rates of organic carbon in many European lakes have increased by at least four to five fold over the last 100-150 years (Anderson et al., 2014).
This piece of research compiled data from about 90 European lakes and found background estimates of carbon burial ~ 5–10 g C m-2 yr–1 compared with an average rate of around 60 g C m-2 yr–1 for lakes subject to eutrophication in recent decades.
They show that the organic carbon burial rates for European eutrophic lakes reflect phosphorus availability – a pollutant coming for example from domestic waste waters and farming – and are considerably higher than previously thought. This has clear implications for our current estimates of regional carbon budgets and for the role lakes may play.
The authors suggest that enhanced organic carbon burial by lakes is one positive side-effect of the otherwise negative impact of the anthropogenic disruption of nutrient cycles: eutrophic lakes are sequestering more organic carbon than at any other time in their history.
Within the Lake BESS project, changes in organic carbon burial rates will be calculated for the study sites in the two lake regions to determine the role of these lakes as carbon sinks and hence in providing the important ecosystem service of climate regulation.
Reference: [include link]
Anderson N.J., Bennion H. & Lotter A.F. (2014) Lake eutrophication and its implications for organic carbon sequestration in Europe. Global Change Biology 20, 2741–2751. doi: 10.1111/gcb.12584