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Heterogeneity Matters: Aggregation Bias of Gas Transfer Velocity Versus Energy Dissipation Rate Relations in Streams

Gianluca Botter, Paolo Peruzzo, Nicola Durighetto

2021Geophysical Research Letters11 citationsDOIOpen Access PDF

Abstract

Abstract The gas transfer velocity, , modulates gas fluxes across air‐water interfaces in rivers. While the theory postulates a local scaling law between and the turbulent kinetic energy dissipation rate , empirical studies usually interpret this relation at the reach‐scale. Here, we investigate how local laws can be integrated along heterogeneous reaches exploiting a simple hydrodynamic model, which links stage and velocity to the local slope. The model is used to quantify the relative difference between the gas transfer velocity of a heterogeneous stream and that of an equivalent homogeneous system. We show that this aggregation bias depends on the exponent of the local scaling law, , and internal slope variations. In high‐energy streams, where , spatial heterogeneity of significantly enhances reach‐scale values of as compared to homogeneous settings. We conclude that small‐scale hydro‐morphological traits bear a profound impact on gas evasion from inland waters.

Topics & Concepts

DissipationScalingKinetic energySTREAMSExponentHomogeneousTurbulenceMechanicsEnvironmental scienceScaling lawScale (ratio)Relative velocityStatistical physicsSpatial heterogeneityEnergy transferPhysicsThermodynamicsClassical mechanicsMathematicsGeometryEcologyChemical physicsBiologyComputer networkComputer sciencePhilosophyQuantum mechanicsLinguisticsHydrology and Watershed Management StudiesOceanographic and Atmospheric ProcessesFish Ecology and Management Studies
Heterogeneity Matters: Aggregation Bias of Gas Transfer Velocity Versus Energy Dissipation Rate Relations in Streams | Litcius