FLUFLUX | Fluvial Meta-Ecosystem Functioning: Unravelling Regional Ecological Controls Behind Fluvial Carbon Fluxes

Summary
Fluvial ecosystems are an important element in the global carbon cycle metabolizing large amounts of terrigenous organic matter (tOM). This contributes to CO2 evasion fluxes that are under continuous reevaluation at the global scale. In contrast, research on the underlying processes is concentrated at the local ecosystem scale. This scale-gap seriously hampers process understanding across scales, limits upscaling accuracy, and reduces our scope of reaction strategies.
Here, I suggest ground-breaking research on ecological processes at the intermediate ‘regional’ scale of the ‘fluvial network‘ to create a deeper mechanistic understanding of biogeochemically relevant carbon fluxes. My starting point is trifold: (1) detrital tOM has extremely high molecular-level diversity that requires consumers of equally high biodiversity for efficient respiration; (2) exactly this biodiversity of heterotrophic microbes, fungi and insects is constrained by metacommunity dynamics unfolding at a larger regional scale; and (3) the rules by which the conspicuously dendritic structure of the fluvial network shapes a metacommunity differ fundamentally from those governing regional diversity patterns of tOM resources.
I hypothesize regional carbon dissimilation in ‘fluvial metaecosystems’ to be the interactive product of spatially partitioned resource and consumer diversities. I posit that this coupling of metacommunity structure to metaecosystem function is influenced by fluvial network topology, anthropogenic network fragmentation, and terrestrial matrix variation. Research will combine experiments in innovative lab-scale metaecosystems, spatially explicit modelling using cellular automata, and field studies spanning gradients of regional anthropogenic impact in real fluvial networks. I expect this cross-disciplinary research at the crucial landscape scale to generate novel mechanistic process understanding behind fluvial carbon fluxes in a world changing at ever faster pace.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/716196
Start date: 01-04-2017
End date: 31-03-2023
Total budget - Public funding: 1 487 171,00 Euro - 1 487 171,00 Euro
Cordis data

Original description

Fluvial ecosystems are an important element in the global carbon cycle metabolizing large amounts of terrigenous organic matter (tOM). This contributes to CO2 evasion fluxes that are under continuous reevaluation at the global scale. In contrast, research on the underlying processes is concentrated at the local ecosystem scale. This scale-gap seriously hampers process understanding across scales, limits upscaling accuracy, and reduces our scope of reaction strategies.
Here, I suggest ground-breaking research on ecological processes at the intermediate ‘regional’ scale of the ‘fluvial network‘ to create a deeper mechanistic understanding of biogeochemically relevant carbon fluxes. My starting point is trifold: (1) detrital tOM has extremely high molecular-level diversity that requires consumers of equally high biodiversity for efficient respiration; (2) exactly this biodiversity of heterotrophic microbes, fungi and insects is constrained by metacommunity dynamics unfolding at a larger regional scale; and (3) the rules by which the conspicuously dendritic structure of the fluvial network shapes a metacommunity differ fundamentally from those governing regional diversity patterns of tOM resources.
I hypothesize regional carbon dissimilation in ‘fluvial metaecosystems’ to be the interactive product of spatially partitioned resource and consumer diversities. I posit that this coupling of metacommunity structure to metaecosystem function is influenced by fluvial network topology, anthropogenic network fragmentation, and terrestrial matrix variation. Research will combine experiments in innovative lab-scale metaecosystems, spatially explicit modelling using cellular automata, and field studies spanning gradients of regional anthropogenic impact in real fluvial networks. I expect this cross-disciplinary research at the crucial landscape scale to generate novel mechanistic process understanding behind fluvial carbon fluxes in a world changing at ever faster pace.

Status

CLOSED

Call topic

ERC-2016-STG

Update Date

27-04-2024
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Horizon 2020
H2020-EU.1. EXCELLENT SCIENCE
H2020-EU.1.1. EXCELLENT SCIENCE - European Research Council (ERC)
ERC-2016
ERC-2016-STG