10,000s
of water bodies across Europe need urgent repair
500 million
EU citizens live, work and play near freshwaters
Our research
has pioneered new water management policies
Saving Europe's freshwaters
Freshwater ecosystems have shaped and benefited humanity from early times. Now, they are in a grave state, facing the highest rates of biodiversity loss of all ecosystems globally. Our research has been critical to implementing major new policies to repair tens of thousands of water bodies across Europe.
Part of our research looks at the work of nature’s iconic engineers, beavers, who are providing new insights into rewilding and restoring agricultural landscapes.
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A pan-European approach to freshwater management
The EU Water Framework Directive (WFD), adopted in 2000, took a pioneering holistic approach to water management. This new approach was based on geographical catchments known as River Basin Districts, rather than the traditional use of administrative or political boundaries.
However, the solutions for improvement are complicated, especially when freshwater ecosystems are impacted by multiple pressures and shared by countries with piecemeal management policies. There was a big challenge in harmonising hundreds of national methods developed for assessing the ecological health of water bodies. Our research tackles these challenges, providing solutions that apply across Europe.
"We’re helping water managers, policy makers and environmental and conservation agencies with their work, especially those implementing EU strategies, such as the 2020 EU Biodiversity Strategy."
Our research
The University’s freshwater science research team, including Professor Nigel Willby, Dr Dan Chapman, Dr Zarah Pattison, Dr Alan Law and Dr Colin Bull, researches and provides scientific advice for national and international water policy and management. Our research addresses two main themes of assessment and monitoring, and restoration and management.
Assessment and monitoring
Before we can restore rivers and lakes, we have to understand how to assess and monitor their ecological health. We have to understand how species respond to their environment as well as monitoring the impact of pressures, such as invasive species, river engineering and lake water levels which have often been overlooked in the past. We also need to create solutions to the challenges of biomonitoring in densely populated river basins and diagnose why the health of water bodies is deteriorating in order to mend them.
We developed tools that are now used by UK agencies to determine freshwater status. We designed the protocols used by the EU for harmonising national assessment methods, and defined nutrient targets required to improve the health of lakes and rivers. These targets have been adopted across Europe.
Restoration and management
This part of our research assesses restoration practices used in lakes and rivers. We can recommend evidence-based actions suitable for the management plans required under the WFD. One example is our review of lake restoration practices for the Broads Authority which shaped their future lake restoration strategy.
Once we understand the relationship between species and their environment, we can better predict how ecosystems will respond to alterations in the environment imposed by management and restoration.
For example, our research and advice on restoring polluted lakes and removing barriers to salmon migration is now being enacted and has been incorporated into management plans in the UK.
Beavers and balsam
Part of our research is looking into the behaviour of an invasive plant, Himalayan balsam, on UK rivers; and how beavers are rewilding habitats on Tayside.
Our study reveals clues as to why the abundance of Himalayan balsam, a notorious invader of river banks, varies dramatically from place to place. The work could help mitigate the impact of this pink-flowered plant, which outcompetes native species, causes shading and reduces the stability of riverbanks, enabling silt to enter the water.
In 2018, our research revealed how beaver-built ponds are far more biodiverse than other wetlands. By cutting trees, beavers create a complex, mosaic of habitats that benefits local wildlife and improves ecosystem resilience. Beaver dams can improve biodiversity, trap pollutants and reduce downstream flooding. Beavers could therefore offer a solution to some of the environmental problems that society is going to face in the coming decades, especially with the effects of climate change. But we have to be careful and weigh these benefits against the potential for occasional negative impacts on fisheries, forestry and farmland.
Nonetheless, this passive restoration approach is now seen as an important part of the rewilding and restoration debate.
See also: Beaver reintroduction key to solving freshwater biodiversity crisis
"Our research justified the thinking behind the reintroduction of beavers. These are amazing ecosystem engineers who create unique habitats. Put simply: anyone can build a pond – but if you want a really great pond, ask a beaver."
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Hosting the Scottish Freshwater Group
Stirling has hosted the Scottish Freshwater Group since 1968 and in 2018, we celebrated its centenary meeting. The group promotes awareness of current issues and research related to the freshwater environment in Scotland. It consists of around 350 members from universities, institutes, government and non-government agencies, industry and interested members of the public.
Our association with the Scottish Freshwater Group reflects our ongoing commitment to research in freshwater science - and our breadth of collaborations with external organisations and other researchers active in this field.
Related publications
White HL, Fellows R, Woodford L, Ormsby MJ, van Biervliet O, Law A, Quilliam RS & Willby NJ (2025) The impact of beaver dams on distribution of waterborne Escherichia coli and turbidity in an agricultural landscape. Science of The Total Environment, 968, p. 178871. https://www.sciencedirect.com/science/article/pii/S0048969725005066?ref=pdf_download&fr=RR-2&rr=93c79e2d1e0bb3ba
The Role of Non-Native Plant Species in Modulating Riverbank Erosion: A Systematic Review
Hardwick J, Hackney C, Keen L, Fitzsimmons C, Willby N & Pattison Z (2025) The Role of Non-Native Plant Species in Modulating Riverbank Erosion: A Systematic Review. River Research and Applications. https://doi.org/10.1002/rra.4420
Multi-pollutant removal dynamics by aquatic plants in monoculture or mixed communities
Fletcher J, Willby NJ, Oliver DM & Quilliam RS (2024) Multi-pollutant removal dynamics by aquatic plants in monoculture or mixed communities. Environmental Research, 263 (1), Art. No.: 120041. https://doi.org/10.1016/j.envres.2024.120041
Law A, Baker A, Sayer CD, Foster G, Gunn IDM, Macadam CR & Willby NJ (2024) Repeatable patterns in the distribution of freshwater biodiversity indicators across contrasting landscapes. Landscape Ecology, 39 (11). https://doi.org/10.1007/s10980-024-01992-z
Invertebrate responses to rewilding: a monitoring framework for practitioners
Cook P, Law A, Pattison Z, WallisDeVries MF & Willby NJ (2024) Invertebrate responses to rewilding: a monitoring framework for practitioners. Restoration Ecology. https://doi.org/10.1111/rec.14195
Optimising species detection probability and sampling effort in lake fish eDNA surveys
Sellers GS, Jerde CL, Harper LR, Benucci M, Di Muri C, Li J, Peirson G, Walsh K, Hatton-Ellis T, Duncan W, Duguid A, Ottewell D, Willby N, Law A & Bean CW (2024) Optimising species detection probability and sampling effort in lake fish eDNA surveys. Metabarcoding and Metagenomics, 8, Art. No.: e104655. https://doi.org/10.3897/mbmg.8.104655