Summary
One of the greatest challenges of the 21st century is to understand and mitigate the effects of climate change on earth ecosystems. Climate change increases the frequency and intensity of hydrological droughts worldwide. In rivers, drying (i.e. the loss of surface water) is a severe disturbance that alters biodiversity and ecosystem functions such as organic matter (OM) decomposition with often negative consequences for ecosystem services (e.g. water purification) and human activities (e.g. water consumption). River networks are an aquatic continuum in a terrestrial matrix in which OM is transported, and organisms disperse laterally: from terrestrial to aquatic environment, vertically: from the riverbed surface to the subsurface and longitudinally: along the network. Drying, modifies OM transport and dispersal by cutting the water continuum, potentially altering an entire river network´s OM decomposition dynamics, and hence carbon cycling and CO2 emissions. Although, much is known about the effect of drying at local scales, very little is known about its effects at the entire river network scale. Only studies done at an appropriate large scale can adequately inform and help to develop an adaptive management that minimizes drying impacts on river ecosystems and human activities. By combining meta-analysis, network-scale field experiments and modelling, MetaDryNet will explore the effects of drying on OM transport and decomposer organism dispersal to determine how drying affects OM decomposition and CO2 emissions in river networks. Using new technologies, novel ecological theories and complex modelling approaches this research is highly innovative and will allow to improve our understanding of how resources and biodiversity are linked in space and time in drying river networks. This project will contribute to advance ecological theories but also offer guidance for river management and conservation under global changes.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/891090 |
| Start date: | 01-01-2021 |
| End date: | 31-12-2022 |
| Total budget - Public funding: | 184 707,84 Euro - 184 707,00 Euro |
Cordis data
Original description
One of the greatest challenges of the 21st century is to understand and mitigate the effects of climate change on earth ecosystems. Climate change increases the frequency and intensity of hydrological droughts worldwide. In rivers, drying (i.e. the loss of surface water) is a severe disturbance that alters biodiversity and ecosystem functions such as organic matter (OM) decomposition with often negative consequences for ecosystem services (e.g. water purification) and human activities (e.g. water consumption). River networks are an aquatic continuum in a terrestrial matrix in which OM is transported, and organisms disperse laterally: from terrestrial to aquatic environment, vertically: from the riverbed surface to the subsurface and longitudinally: along the network. Drying, modifies OM transport and dispersal by cutting the water continuum, potentially altering an entire river network´s OM decomposition dynamics, and hence carbon cycling and CO2 emissions. Although, much is known about the effect of drying at local scales, very little is known about its effects at the entire river network scale. Only studies done at an appropriate large scale can adequately inform and help to develop an adaptive management that minimizes drying impacts on river ecosystems and human activities. By combining meta-analysis, network-scale field experiments and modelling, MetaDryNet will explore the effects of drying on OM transport and decomposer organism dispersal to determine how drying affects OM decomposition and CO2 emissions in river networks. Using new technologies, novel ecological theories and complex modelling approaches this research is highly innovative and will allow to improve our understanding of how resources and biodiversity are linked in space and time in drying river networks. This project will contribute to advance ecological theories but also offer guidance for river management and conservation under global changes.Status
CLOSEDCall topic
MSCA-IF-2019Update Date
28-04-2024
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