Size, shape and dynamics of large-scale turbulent flow structures in a gravel-bed river

ANDREÉ G. ROY; THOMAS BUFFIN-BÉLANGER; HÈLÉNE LAMARRE; ALISTTAIR D. KIRKBRIDE

doi:10.1017/S0022112003006396

Abstract

In this paper, we present a detailed investigation of the size, scale and dynamics of macro-turbulent flow structures in gravel-bed rivers. We used an array of seven electromagnetic current meters with high resolution in both space and time to measure the streamwise velocity fluctuations in a gravel-bed river. The array was deployed successively in various configurations in order to quantify the vertical, lateral and longitudinal extent of the flow structures and to estimate their advecting velocities. To depict the spatial and temporal properties of the flow structures, we used space–time velocity matrices, space–time correlation analysis and coherent-structure detection schemes. The results show that the large-scale turbulent flow structures in a gravel-bed river occupy the entire depth of the flow and that they are elongated and narrow. The length of the structures is 3 to 5 times the flow depth while the width is between 0.5 and 1 times flow depth. In spite of the high roughness of the bed, these values are similar to those reported in the literature for laboratory experiments on large-scale turbulent flow structures. The dynamics of the large-scale turbulent flow structures investigated using flow visualization highlight the interactions between the outer flow region and the near-bed region. Our evidence suggests that large-scale flow incursions trigger ejections in the near-bed region that can develop into megabursts that can reach the water surface.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

2004. Environmental Hydraulics and Sustainable Water Management, Two Volume Set. p. 1223.

Buffin-Bélanger, Thomas and Roy, André G. 2005. 1 min in the life of a river: selecting the optimal record length for the measurement of turbulence in fluvial boundary layers. Geomorphology, Vol. 68, Issue. 1-2, p. 77.

Kramer, C. M. and Papanicolaou, A. N. 2005. The Effects of Relative Submergence on Cluster Formation in Gravel Bed Streams. p. 1.

Sambrook Smith, Gregory H. and Nicholas, Andrew P. 2005. Effect on flow structure of sand deposition on a gravel bed: Results from a two‐dimensional flume experiment. Water Resources Research, Vol. 41, Issue. 10,

Tritico, Hans M. and Hotchkiss, Rollin H. 2005. Unobstructed and Obstructed Turbulent Flow in Gravel Bed Rivers. Journal of Hydraulic Engineering, Vol. 131, Issue. 8, p. 635.

Lamarre, Hélène and Roy, André G. 2005. Reach scale variability of turbulent flow characteristics in a gravel-bed river. Geomorphology, Vol. 68, Issue. 1-2, p. 95.

Fox, J. F. Patrick, A. and Wood, S. 2006. The Use of LSPIV to Measure Large Streamwise Vortices. p. 1.

WATANABE, Katsutoshi SAGA, Takanori and KUNIHIRO, Eiji 2006. INNER STRUCTURE OF HERICOIDAL FLOW IN TURBULENT OPEN CHANNEL FLOW WITH LONGITUDINAL RIDGE ELEMENTS. Doboku Gakkai Ronbunshuu B, Vol. 62, Issue. 2, p. 186.

Cooper, James R. Tait, Simon J. and Horoshenkov, Kirill V. 2006. Determining hydraulic resistance in gravel‐bed rivers from the dynamics of their water surfaces. Earth Surface Processes and Landforms, Vol. 31, Issue. 14, p. 1839.

Cotel, Aline J. Webb, Paul W. and Tritico, Hans 2006. Do Brown Trout Choose Locations with Reduced Turbulence?. Transactions of the American Fisheries Society, Vol. 135, Issue. 3, p. 610.

Buffin‐Bélanger, Thomas Rice, Stephen Reid, Ian and Lancaster, Jill 2006. Spatial heterogeneity of near‐bed hydraulics above a patch of river gravel. Water Resources Research, Vol. 42, Issue. 4,

Marquis, Geneviève A. and Roy, André G. 2006. Effect of flow depth and velocity on the scales of macroturbulent structures in gravel‐bed rivers. Geophysical Research Letters, Vol. 33, Issue. 24,

Lacey, R. W. Jay and Roy, André G. 2007. A comparative study of the turbulent flow field with and without a pebble cluster in a gravel bed river. Water Resources Research, Vol. 43, Issue. 5,

2007. Gravel-Bed Rivers VI: From Process Understanding to River Restoration. Vol. 11, Issue. , p. 105.

Keylock, C. J. 2007. The visualization of turbulence data using a wavelet‐based method. Earth Surface Processes and Landforms, Vol. 32, Issue. 4, p. 637.

Lacey, R. W. Jay Legendre, Pierre and Roy, André G. 2007. Spatial‐scale partitioning of in situ turbulent flow data over a pebble cluster in a gravel‐bed river. Water Resources Research, Vol. 43, Issue. 3,

Detert, Martin Klar, Michael Wenka, Thomas and Jirka, Gerhard H. 2007. Gravel-Bed Rivers VI: From Process Understanding to River Restoration. Vol. 11, Issue. , p. 85.

Wilcox, Andrew C. and Wohl, Ellen E. 2007. Field measurements of three-dimensional hydraulics in a step-pool channel. Geomorphology, Vol. 83, Issue. 3-4, p. 215.

Strom, Kyle B. and Papanicolaou, Athanasios N. 2007. ADV Measurements around a Cluster Microform in a Shallow Mountain Stream. Journal of Hydraulic Engineering, Vol. 133, Issue. 12, p. 1379.

Hardy, Richard J. Lane, Stuart N. Ferguson, Robert I. and Parsons, Daniel R. 2007. Emergence of coherent flow structures over a gravel surface: A numerical experiment. Water Resources Research, Vol. 43, Issue. 3,

Download full list

Article contents

Size, shape and dynamics of large-scale turbulent flow structures in a gravel-bed river

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Size, shape and dynamics of large-scale turbulent flow structures in a gravel-bed river

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests