Evaluation of the Logarithmic Law of the Wall for River Flows

Petrie, John; Diplas, Panayiotis

doi:10.1002/rra.2920

Cited by 13 publications

(37 citation statements)

References 31 publications

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“…In some parts of the water column, the measured flow velocity had a logarithmic relation to the water depth, which could best be assessed through semilogarithmic flow velocity profiles. These were created by using the water depth-averaged flow velocity (u) versus the natural logarithm of the vertical distance from the water surface to the measurements (z) as given by each data point measured by the ADCP [72][73][74][75][76]. Although, this logarithmic law relation is thought to only apply to the lowest 20% of the water depth, it has been previously applied throughout the water column in order to estimate flow velocity profiles [72,73,77,78].…”

Section: Near-bottom Flow Velocity Mappingmentioning

confidence: 99%

“…Since the ADCP measurements were constrained to the top ~ 6 m of the total water depth, the logarithmic law was applied in order to estimate the near-bottom flow velocity. A linear regression was fitted to the logarithmic region visible in the flow velocity profiles by including at least three successive raw data points nearest to the bottom [74]. Linear regressions were acceptable if R 2 > 0.9.…”

Section: Near-bottom Flow Velocity Mappingmentioning

confidence: 99%

See 1 more Smart Citation

Assessing Habitat Suitability for Native and Alien Freshwater Mussels in the River Waal (the Netherlands), Using Hydroacoustics and Species Sensitivity Distributions

Flores

Collas

Mehler

et al. 2021

Environ Model Assess

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Longitudinal training dams (LTDs) in the river Waal are novel river training structures that protect the littoral zone from the adverse effects of navigation providing new habitats for riverine macroinvertebrates. In order to inform river management and to better understand their ecological value for native and alien mussel species, it is important to assess the habitat suitability of the protected LTD shore channels. We applied spatial hydroacoustics surveys consisting of side-scan sonar (SSS) and acoustic Doppler current profiler (ADCP) of the substrate type, water depth and flow velocity in three shore channels in combination with species sensitivity distributions (SSDs) to predict habitat suitability for native and alien mussel species. SSDs allowed for the prediction of habitat suitability as a potentially occurring fraction (POF) of a species pool. High substrate type, water depth, and near-bottom flow velocity POFs were found for ≥ 70%, 100%, and 4–51% of the total shore channel area, respectively, suggesting that shore channels provide suitable habitat for both native and alien mussel species. To enhance the shore channels as habitat for native mussel species, we recommend increasing shallow areas dominated by fine (silt/clay) and sand substrate types with low near-bottom flow velocities (near 0 m/s). In contrast, the total area of hard substrate (e.g., boulders) in the shore channels should be reduced as it strongly favored invasive alien mussel species in our study. Future research should include additional abiotic parameters to enhance the habitat suitability predictions and compare the results for different riverine habitats.

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Section: Near-bottom Flow Velocity Mappingmentioning

confidence: 99%

Section: Near-bottom Flow Velocity Mappingmentioning

confidence: 99%

Assessing Habitat Suitability for Native and Alien Freshwater Mussels in the River Waal (the Netherlands), Using Hydroacoustics and Species Sensitivity Distributions

Flores

Collas

Mehler

et al. 2021

Environ Model Assess

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show abstract

“…This velocity data was then used to calculate the near bed shear velocity (up; Eq. 2), assuming the flow followed a standard logarithmic profile away from both the near-bed boundary layer and internal velocity maximum (Petrie and Diplas, 2015). The velocity profile was fitted over 0.01-0.02 m away from the bed in order to avoid both the near-bed viscous sublayer and the velocity maximum where the profile may deviate from the logarithmic form.…”

Section: Data Processingmentioning

confidence: 99%

Relating the Flow Processes and Bedforms of Steady-State and Waning Density Currents

et al. 2020

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“…Estas regiones se evalúan por la relación ⁄ , donde es la coordenada vertical y es la profundidad o tirante del flujo. En la región cercana al fondo , la velocidad principal es descrita por la clásica "ley de pared" (Coles, 1956), que se compone de tres zonas: subcapa viscosa, amortiguamiento y logarítmica (Petrie & Diplas, 2016;Spalding, 1961). La existencia de la subcapa viscosa y la zona de amortiguamiento está en función de la rugosidad del fondo, por ejemplo, si el valor de escala de rugosidad adimensional ( , donde es la rugosidad absoluta, es la velocidad de corte y es la viscosidad cinemática), el flujo se considera con fondo hidráulicamente liso y están presentes las tres zonas.…”

Section: Introductionunclassified

“…Este modelo logarítmico se ha utilizado para caracterizar el campo de velocidad de flujos turbulentos en ríos (Ferro & Baiamonte, 2019, Instituto Mexicano de Tecnología del Agua. Open Access bajo la licencia CC BY-NC-SA 4.0 (https://creativecommons.org/licenses/by-nc-sa/4.0/) 1994; Petrie & Diplas, 2016), canales (Auel, Albayrak, & Boes, 2014;Tominaga & Nezu, 1992) y tuberías (Bailey, Vallikivi, Hultmark, & Smits, 2014;Perry, Hafez, & Chong, 2001).…”

Section: Introductionunclassified