Thermal regime, together with lateral connectivity, control aquatic invertebrate composition in river floodplains

Large river floodplains are dynamic environments, where alternating low and high flows are key ecological processes shaping aquatic biota. As a result of fluctuations in flow in floodplain channels, the diversity of benthic assemblages is assumed to result from the balance between surface flow conne...

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Bibliographic Details
Published in:Freshwater biology 2022-10, Vol.67 (10), p.1774-1788
Main Authors: Marle, Pierre, Riquier, Jérémie, Timoner, Pablo, Mayor, Hélène, Slaveykova, Vera I., Castella, Emmanuel
Format: Article
Language:English
Subjects:
Aquatic animals
Aquatic biota
Aquatic invertebrates
Aquatic organisms
Benthos
Biodiversity
Biodiversity and Ecology
Biota
Braided streams
Braiding
Channels
Composition
Connectivity
Ecological effects
Ecology, environment
Environmental Sciences
floodplain processes
Floodplains
generalised dissimilarity model
Groundwater
Groundwater supply
hydrological connectivity
Hydrology
Inertia
Invertebrates
Life Sciences
Low flow
Overflow
Rhone River
Rivers
Shear stress
species turnover
Specific heat
Surface flow
Surface water
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Summary:Large river floodplains are dynamic environments, where alternating low and high flows are key ecological processes shaping aquatic biota. As a result of fluctuations in flow in floodplain channels, the diversity of benthic assemblages is assumed to result from the balance between surface flow connections, which are dominant during high flows, and groundwater inputs, which are dominant during low flows. However, the relative importance of these inputs in explaining aquatic invertebrate diversity has never been tested. The response of aquatic invertebrates to hydrological changes of a river floodplain was investigated in seven braided and six braided–anastomosed floodplain channels of the French upper Rhône River that are fed by three different processes: groundwater supply (which controls the thermal inertia of the water bodies), surface slow flow connections (i.e. diffuse overbank flows; passive overflow), and surface shear stress‐related connections (i.e. condensed flows; active overflow) during high flows. Generalised dissimilarity models indicated that floodplain invertebrate composition had complex relationships with the three processes considered. The relative importance of the latter appeared dependent upon the morphology of the floodplain channels. In the braided channels, the effects of shear stress‐related connections were more prominent than in the anastomosed ones, for which the effects of the three processes were more similar. Overall, the diversity of flow connections, that is, lateral surface water connections (both shear stress‐related and slow, as defined above) and vertical connection with groundwater (inferred through thermal inertia) enhanced the species turnover at the reach scale. Thermal inertia influenced invertebrate composition when, during low flow periods, surface flow connections had limited effect. Our results highlighted that the role of hydrologic connectivity upon floodplain diversity cannot be reduced to a single process. They also indicate the importance of vertical connectivity for maintaining biodiversity in floodplain habitats where surface flow connectivity is neither frequent nor constant.
ISSN:0046-5070
1365-2427
DOI:10.1111/fwb.13974