Waves and currents over a fixed rippled bed: 3. Bottom and apparent roughness for spectral waves and currents

Mathisen, Paul Peter; Madsen, Ole Secher

doi:10.1029/1999jc900114

Cited by 36 publications

(41 citation statements)

References 18 publications

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“…Moreover, Madsen's [1994] relationship between friction factor and bed roughness is based on the assumption that k N is independent of ambient hydrodynamic conditions. This assumption has been validated for fixed beds in laboratory studies [Mathisen and Madsen, 1999 [Méndez and Losada, 2004;Méndez et al, 1999]. To reduce the impact of this effect on the present analysis, all instruments were placed inside the meadow, at least 100 m away from its leading and trailing edge.…”

Section: Discussionmentioning

confidence: 99%

“…While a current is likely to cause bending of the flexible vegetation leaves, it is not known in detail how the current affects sea grass. Additionally, experiments over fixed beds showed that k N is bed specific and is not affected by changing hydrodynamic conditions [Mathisen and Madsen, 1999]. Equation (18) should therefore yield a good first approximation, especially as values of C m are generally close to unity [Madsen, 1994].…”

Section: Wave Attenuationmentioning

confidence: 99%

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Spatial and seasonal variation in wave attenuation overZostera noltii

Paul¹,

Amos²

2011

J. Geophys. Res.

120

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[1] Wave attenuation is a recognized function of sea grass ecosystems which is believed to depend on plant characteristics. This paper presents field data on wave attenuance collected over a 13 month period in a Zostera noltii meadow. The meadow showed a strong seasonality with high shoot densities in summer (approximately 4,600 shoots/m 2 ) and low densities in winter (approximately 600 shoots/m 2 ). Wave heights and flow velocities were measured along a transect at regular intervals during which the site was exposed to wind waves and boat wakes that differ in wave period and steepness. This difference was used to investigate whether wave attenuation by sea grass changes with hydrodynamic conditions. A seasonal change in wave attenuation was observed from the data. Results suggest that a minimum shoot density is necessary to initiate wave attenuation by sea grass. Additionally, a dependence of wave attenuation on hydrodynamics was found. Results suggest that the threshold shoot density varies with wave period and a change in energy dissipation toward the shore was observed once this threshold was exceeded. An attempt was made to quantify the bed roughness of the meadow; the applicability of this roughness value in swaying vegetation is discussed. Finally, the drag coefficient for the meadow was computed: A relationship between wave attenuance and vegetation Reynolds number was found which allows comparing the wave attenuating effect of Zostera noltii to other plant species.Citation: Paul, M., and C. L. Amos (2011), Spatial and seasonal variation in wave attenuation over Zostera noltii, J. Geophys.

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Section: Discussionmentioning

confidence: 99%

Section: Wave Attenuationmentioning

confidence: 99%

Spatial and seasonal variation in wave attenuation overZostera noltii

Paul¹,

Amos²

2011

J. Geophys. Res.

120

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“…Previous studies of bottom friction beneath random waves have been undertaken by Madsen [10][11][12][13][14][15][16][17][18][19] as well as Myrhaug and Holmedal [20][21][22]. Madsen [10] gave explicit wave friction factor formulas for spectral wave-current boundary layer flow.…”

Section: Introductionmentioning

confidence: 99%

Bottom friction and bedload sediment transport caused by boundary layer streaming beneath random waves

Myrhaug

Holmedal

Rue

2004

Applied Ocean Research

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“…Mathisen and Madsen [31][32][33] presented some results of the experimental investigation of the WBBL in the presence and in the absence of a constant current. It was shown that a sole scale of bottom irregularities can be used to characterize the state of the boundary layer and, moreover, that this scale remains invariable both in the presence and in the absence of a constant current.…”

mentioning

confidence: 98%

“…The results of laboratory and in-situ experiments carried out with an aim of investigation of the structure of nonstationary (fluctuating and wave) bottom boundary layers over smooth and rough bottoms are described in [15,[19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35]. Numerous works are devoted to the analysis of the conditions of development of turbulence and its characteristics in bottom boundary layers (see, e.g., [18,36]).…”

mentioning

confidence: 99%

Structure of the Wave Bottom Boundary Layer over Smooth and Rough Bottoms

Kushnir

2005

Phys Oceanogr

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The comparison of six well-known models of the wave bottom boundary layer shows that they are identical in the case of a smooth bottom but exhibit serious differences for the other types of conditions. The thickness of the wave bottom boundary layer and the coefficient of vertical diffusion of momentum are studied by using the relations of the k -ε -model. The validity of these estimates is checked by comparing the measured and computed values of the friction velocity. This comparison demonstrates fairly good agreement between the results characterized by a coefficient of correlation equal to 0.851.

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Waves and currents over a fixed rippled bed: 3. Bottom and apparent roughness for spectral waves and currents

Cited by 36 publications

References 18 publications

Spatial and seasonal variation in wave attenuation overZostera noltii

Spatial and seasonal variation in wave attenuation overZostera noltii

Bottom friction and bedload sediment transport caused by boundary layer streaming beneath random waves

Structure of the Wave Bottom Boundary Layer over Smooth and Rough Bottoms

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