Diversity in Upland Rivers for Ecosystem Service Sustainability - DURESS
Lead Research Organisation:
Queen Mary University of London
Department Name: Sch of Biological and Chemical Sciences
Abstract
With the UK's water valued at £200 billion p.a., Britain's 389,000 km of river ecosystems are arguably our most important. In addition to providing water, they supply other major ecosystem services such as the regulation of flooding and water quality; support to adjacent ecosystems by supplying energy and nutrients; and large cultural value for charismatic organisms, recreation, and education. However, the ways in which organisms and ecosystem functions maintain these services in rivers are extremely poorly understood. This is despite large ongoing effects on river organisms from changing catchment land use, and increasingly also from climate change. Cost implications are large and result, for example, from impacts on recreational fisheries, water treatment costs, and high value river biodiversity. By contrast, opportunities to use management positively to increase the ecosystem service value of rivers by enhancing beneficial in-river organisms have barely been considered.
In this project, we will focus on four examples of river ecosystem services chosen to be explicitly biodiversity-mediated: the regulation of water quality; the regulation of decomposition; fisheries and recreational fishing; and river birds as culturally valued biodiversity. Each is at risk from climate/land use change, illustrating their sensitivity to disturbance thresholds over different time scales. These services vary in attributable market values, and all require an integrated physical, biogeochemical, ecological and socio-economic science perspective that none of the project partners could deliver alone.
Using river microbes, invertebrates, fish and river birds at levels of organisation from genes to food webs, we will test the overarching hypothesis that: "Biodiversity is central to the sustainable delivery of upland river ecosystem services under changing land-use and climate". Specifically, we will ask: 1. What is the range of services delivered by upland rivers, and which are biologically mediated? 2. What are the links between biodiversity (from genes to food webs) and service delivery? 3. How does river biodiversity affect the rate or resilience of ecosystem service delivery through time? 4. How do changes in catchment land use/ management and climate affect river biota? 5. How should river biodiversity be managed to sustain ecosystem services?
At spatial scales ranging from small experimental catchments to the whole region, and at temporal scales from sub-annual to over three decades, the work will be carried out in upland Wales as a well-defined geographical area of the UK that is particularly rich in the spatially extensive and long-term data required for the project.
In this project, we will focus on four examples of river ecosystem services chosen to be explicitly biodiversity-mediated: the regulation of water quality; the regulation of decomposition; fisheries and recreational fishing; and river birds as culturally valued biodiversity. Each is at risk from climate/land use change, illustrating their sensitivity to disturbance thresholds over different time scales. These services vary in attributable market values, and all require an integrated physical, biogeochemical, ecological and socio-economic science perspective that none of the project partners could deliver alone.
Using river microbes, invertebrates, fish and river birds at levels of organisation from genes to food webs, we will test the overarching hypothesis that: "Biodiversity is central to the sustainable delivery of upland river ecosystem services under changing land-use and climate". Specifically, we will ask: 1. What is the range of services delivered by upland rivers, and which are biologically mediated? 2. What are the links between biodiversity (from genes to food webs) and service delivery? 3. How does river biodiversity affect the rate or resilience of ecosystem service delivery through time? 4. How do changes in catchment land use/ management and climate affect river biota? 5. How should river biodiversity be managed to sustain ecosystem services?
At spatial scales ranging from small experimental catchments to the whole region, and at temporal scales from sub-annual to over three decades, the work will be carried out in upland Wales as a well-defined geographical area of the UK that is particularly rich in the spatially extensive and long-term data required for the project.
Planned Impact
The research findings of the project will have a direct impact on academic researchers, the water industry, conservationists, land managers, policy makers and regulators, and the general public. Impact will be maximised by the participation in the project of representatives of each of these beneficiaries.
Academic beneficiaries: Detailed information on novel methods and approaches to quantify the key aspects of biodiversity that underpin delivery of ecosystem services, and to identify key thresholds and/or resilience in service delivery will be important for community ecologists, system ecologists, hydrologists, and social-economic scientists. Key harmonised and updated environmental databases on rivers as well as information for climate change adaptation and land use management will bring further benefit, in particular to aid development of valuation methods for ecosystems.
The water industry: In deepening our understanding of the relationship between landuse/management and climate changes and river ecosystem processes, this project will help the water industry implement a whole catchment approach to water quality management. In particular it will help to identify options to reduce and manage impacts on water quality, notably in areas that add large costs to water treatment such as elevated nitrate and Dissolved Organic Carbon content, color, and waterborne pathogens that are not controlled using standard water disinfection such as Cryptosporidium.
Land managers: Management of land to minimize impacts on rivers and their ecosystems is a central aim of River Basin Management Plans to deliver compliance with the Water Framework Directive. Agri-environment schemes are a key delivery mechanism where managers need better information on the resilience of river ecosystems and the sensitivity of land use to biodiversity and ecosystem health. This is particularly in the context of meeting the challenge of climate change and the possible ways that land use changes may occur to mitigate climate change and to adapt to climate change.
Conservation managers: The project will provide better information on how protecting and enhancing biodiversity may increase the resilience to deliver ecosystem services, notably in the face of land and climate changes. This will enable conservation efforts that currently revolve around flora and fauna to have a stronger justification in terms of delivering human benefits. The ability to use valuation methods to assess and decide on management options will add greatly to the rigour of these processes and help to justify implementation.
Policy makers and regulators: The project will help this group to develop measures which deliver on the objective of achieving good ecological status of rivers. Valuation methods will help to decide on how management schemes should be designed to optimize delivery of ecosystem services, and to design ways to achieve resilience to the challenges of environmental change.
General public: Most people do not have a clear idea of the way that conservation measures are designed and implemented. By linking biodiversity to ecosystem services and their values, the public will have a better understanding of what conservation policies are trying to achieve. As well as being crucial to ecosystem function the project will show the considerable amenity value of river systems.
Academic beneficiaries: Detailed information on novel methods and approaches to quantify the key aspects of biodiversity that underpin delivery of ecosystem services, and to identify key thresholds and/or resilience in service delivery will be important for community ecologists, system ecologists, hydrologists, and social-economic scientists. Key harmonised and updated environmental databases on rivers as well as information for climate change adaptation and land use management will bring further benefit, in particular to aid development of valuation methods for ecosystems.
The water industry: In deepening our understanding of the relationship between landuse/management and climate changes and river ecosystem processes, this project will help the water industry implement a whole catchment approach to water quality management. In particular it will help to identify options to reduce and manage impacts on water quality, notably in areas that add large costs to water treatment such as elevated nitrate and Dissolved Organic Carbon content, color, and waterborne pathogens that are not controlled using standard water disinfection such as Cryptosporidium.
Land managers: Management of land to minimize impacts on rivers and their ecosystems is a central aim of River Basin Management Plans to deliver compliance with the Water Framework Directive. Agri-environment schemes are a key delivery mechanism where managers need better information on the resilience of river ecosystems and the sensitivity of land use to biodiversity and ecosystem health. This is particularly in the context of meeting the challenge of climate change and the possible ways that land use changes may occur to mitigate climate change and to adapt to climate change.
Conservation managers: The project will provide better information on how protecting and enhancing biodiversity may increase the resilience to deliver ecosystem services, notably in the face of land and climate changes. This will enable conservation efforts that currently revolve around flora and fauna to have a stronger justification in terms of delivering human benefits. The ability to use valuation methods to assess and decide on management options will add greatly to the rigour of these processes and help to justify implementation.
Policy makers and regulators: The project will help this group to develop measures which deliver on the objective of achieving good ecological status of rivers. Valuation methods will help to decide on how management schemes should be designed to optimize delivery of ecosystem services, and to design ways to achieve resilience to the challenges of environmental change.
General public: Most people do not have a clear idea of the way that conservation measures are designed and implemented. By linking biodiversity to ecosystem services and their values, the public will have a better understanding of what conservation policies are trying to achieve. As well as being crucial to ecosystem function the project will show the considerable amenity value of river systems.
Publications
Thompson M
(2017)
Large woody debris "rewilding" rapidly restores biodiversity in riverine food webs
in Journal of Applied Ecology
Perkins DM
(2021)
Systematic variation in food web body-size structure linked to external subsidies.
in Biology letters
Perkins DM
(2018)
Bending the rules: exploitation of allochthonous resources by a top-predator modifies size-abundance scaling in stream food webs.
in Ecology letters
Perkins DM
(2015)
Higher biodiversity is required to sustain multiple ecosystem processes across temperature regimes.
in Global change biology
Gray C
(2015)
Joining the dots: An automated method for constructing food webs from compendia of published interactions
in Food Webs
Description | We have discovered various means by which stream food webs promote and maintain different ecosystem processes and services. In particular our work has shown that river communities are strongly structured by body size and that metabolic scaling can be applied to predict such size-structure and the the flow of energy through these food webs. Our research has also highlighted the environmental context of these relationships with the effects of land use having major implications for the structure of river food webs and services such as fish production. |
Exploitation Route | A host of stakeholders are involved in the project (e.g. Forestry commission, Welsh Water, Environment agency and RSPB ) for which dissemination of results has been ongoing throughout. |
Sectors | Environment |
URL | http://nerc-duress.org/ |
Description | Presentations to local Citizen Science groups |
First Year Of Impact | 2015 |
Sector | Communities and Social Services/Policy,Education,Environment |
Impact Types | Societal |