Towards (better) fluvial meta-ecosystem ecology: a research perspective

Towards (better) fluvial meta-ecosystem ecology: a research perspective

Rivers are an important component of the global carbon cycle and contribute to atmospheric carbon exchange disproportionately to their total surface area. Largely, this is because rivers efficiently mobilize, transport and metabolize terrigenous organic matter (OM). Notably, our knowledge about the...

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Bibliographic Details
Published in:Npj Biodiversity Vol. 3; no. 1; pp. 3 - 10
Main Authors: Talluto, Lauren, Del Campo, Rubén, Estévez, Edurne, Altermatt, Florian, Datry, Thibault, Singer, Gabriel
Format: Journal Article
Language:English
Published: England Springer Nature B.V 01-01-2024
Nature
Nature Publishing Group UK
Nature Portfolio
Subjects:
Anthropogenic factors
Biodiversity
Biodiversity loss
Biogeochemistry
Carbon
Carbon cycle
Connectivity
Consumers
Ecological function
Ecosystems
Environmental Sciences
Fluxes
Human influences
Oceans
Organic matter
Particle size
River ecology
River networks
Rivers
Carbon cycle
Limnology
Community ecology
Ecosystem ecology
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Summary:Rivers are an important component of the global carbon cycle and contribute to atmospheric carbon exchange disproportionately to their total surface area. Largely, this is because rivers efficiently mobilize, transport and metabolize terrigenous organic matter (OM). Notably, our knowledge about the magnitude of globally relevant carbon fluxes strongly contrasts with our lack of understanding of the underlying processes that transform OM. Ultimately, OM processing en route to the oceans results from a diverse assemblage of consumers interacting with an equally diverse pool of resources in a spatially complex network of heterogeneous riverine habitats. To understand this interaction between consumers and OM, we must therefore account for spatial configuration, connectivity, and landscape context at scales ranging from local ecosystems to entire networks. Building such a spatially explicit framework of fluvial OM processing across scales may also help us to better predict poorly understood anthropogenic impacts on fluvial carbon cycling, for instance human-induced fragmentation and changes to flow regimes, including intermittence. Moreover, this framework must also account for the current unprecedented human-driven loss of biodiversity. This loss is at least partly due to mechanisms operating across spatial scales, such as interference with migration and habitat homogenization, and comes with largely unknown functional consequences. We advocate here for a comprehensive framework for fluvial networks connecting two spatially aware but disparate lines of research on (i) riverine metacommunities and biodiversity, and (ii) the biogeochemistry of rivers and their contribution to the global carbon cycle. We argue for a research agenda focusing on the regional scale-that is, of the entire river network-to enable a deeper mechanistic understanding of naturally arising biodiversity-ecosystem functioning coupling as a major driver of biogeochemically relevant riverine carbon fluxes.
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ISSN:2731-4243
2731-4243
DOI:10.1038/s44185-023-00036-0