Experimental investigations were carried out in the
Manchester Tidal flow Facility (MTF) to study the flow patterns in
the region around and adjacent to a hypothetical headland in tidal
(oscillatory) ambient flow. The Planar laser-induced fluorescence
(PLIF) technique was used for visualization, with fluorescent dye
released at specific points around the headland perimeter and in its
adjacent recirculation zone. The flow patterns can be generalized into
the acceleration, stable flow and deceleration stages for each halfcycle,
with small variations according to location, which are more
distinct for low Keulegan-Carpenter number (KC) cases. Flow
patterns in the mixing region are unstable and complex, especially in
the recirculation zone. The flow patterns are in agreement with
previous visualizations, and support previous results in steady
ambient flow. It is suggested that the headland lee could be a viable
location for siting of pollutant outfalls.
[1] D., Chen, F. E. Tang, C. Chen, "PLIF study of pollutant trapping and 3-
D plume structures in recirculation zones around a headland: steady and
tidal currents", In Proc. of the Int. Symp. on Shallow Flows, ASCE,
Holland, 2003
[2] D. Chen, F. E. Tang, C. Chen, "Pollutant trapping at a coastal headland",
J. of Waterway, Port, Coastal and Ocean Eng., vol. 131, no. 3, pp. 98-
114, 2005
[3] L. Loubersac, "Application of high resolution satellite data in the
observation of coastal environment. The case of SPOT simulations
within the framework of ecological survey of Brittany coasts". Special
publication, European Space Agency, 1983
[4] R. D. Pingree, G. T. Mardell, L. Maddock, "Tidal mixing in the channel
isles region derived from the results of remote sensing and
measurements at sea". Estuarine, Coastal and Shelf Science, vol. 20, pp.
1 - 18, 1985
[5] T. F. Duda, and C. S. Cox, "Vorticity measurement in a region of coastal
ocean eddies by observation of near inertial oscillations", Geophys. Res.
Lett., vol. 14, no. 8, pp. 793-796, 1987
[6] P. A. Davies, L. A. Mofor, "Observations of flow separation by an
isolated island". Int. J. of Remote Sensing, vol. 11, no.5, 1990
[7] W. R. Geyer, R. Signell, "Measurements of tidal flow around a headland
with a shipboard acoustic doppler current profiler". J. of Geophys. Res.,
vol. 95, no. C3, 1990
[8] M. Gade, W. Alpers, "Using ERS2-SAR images for routine observation
of marine pollution in European coastal waters". The Sci. of the Total
Environment. vol. 237/238, pp. 441 - 448, 1999
[9] Q. Y. Zhang, 2006. "Comparison of two three-dimensional
hydrodynamic modeling systems for coastal tidal motion". Ocean Eng.
vol. 33. pp. 137 - 151, 2006
[10] P. L. Murphy, A. Valle-Levinson, "Tidal and residual circulation in the
St. Andrew Bay system, Florida". Continental Self Research, vol. 28. pp.
2678 - 2688, 2008
[11] Y. Coeffe, S. Courtier, B. Latteux, "Tidal sea mathematical modeling:
current applications and future developments". Coastal Eng., vol. 11, pp.
479 - 511, 1987
[12] R. A. Falconer, E. Wolanski, L. Mardapitta Hadjipandeli, "Modelling
tidal circulation in an island-s wake". J. of Waterway, Port, Coastal and
Ocean Eng., vol. 112, Iss. 2, pp. 234-254, 1986
[13] R. A. Falconer, L. Mardapitta Hadjipandeli, "Bathymetric and shear
stress effects on an island-s wake: a computational model study".
Coastal Eng., vol. 11, pp. 57 - 86, 1987
[14] R. P. Signell, W. R. Geyer, 1991. "Transient eddy formation around
headlands". J. of Geophys. Res., vol. 96, no. C2, 1991
[15] D. Galloway, E. Wolanski, B. King, "Modelling eddy formations in
coastal waters: A comparison between model capabilities". Proc. of the
conf. on Estuarine and Coastal Modelling, 1995, pp. 13 - 25.
[16] S. A. Socolofsky, G. H. Jirka, "Large-scale flow structures and stability
in shallow flows". J. of Environmental Eng. Sci. vol. 3, Iss. 5, pp. 451 -
462, 2004
[17] G. H. Jirka, "Large-scale flow structures and mixing processes in
shallow flows". J. of Hyd. Res. vol. 39, Iss. 6, pp. 567 - 573, 2001
[18] C. Dong, J. C. McWilliams, "A numerical study of island wakes in the
Southern California Bight", Continental Shelf Research, vol. 27, no. 9, pp.
1233-1248, 2007
[19] M. J. Alaee, C. Pattiaratchi, G. Ivey, "Numerical simulation of the
summer wake of Rottnest Island, Western Australia", Dynamics of
Atmospheres and Oceans, vol. 43, no. 3-4, pp. 171-198, 2007
[20] I. M. Brooks, S. Soderberg, M. Tjernstrom, "The turbulence structure of
the stable atmospheric boundary layer around a coastal headland: aircraft
observations and modeling results", Boundary Layer Meteorology, vol.
107, pp. 531-559, 2003
[21] P. F. Coutis, J. H. Middleton, "The physical and biological impact of a
small island wake in the deep ocean". Deep Sea Research I. vol. 49, pp.
1341 - 1361, 2002
[22] O. Leuchter, J. L. Solignac, "Experimental investigation of the turbulent
structure of vortex wakes". Proc. of the 4th Int. Symp. on Turbulent
Shear Flows, 1985, pp. 156 - 168.
[23] P. Menzel, F. Huttmann, M. Brede, A. Leder, "Experimental
investigations of mixing processes in the wake of a circular cylinder in
stratified flows". Proc. of the Conf. on Multiphase flow: The Ultimate
Measurement Challenge, 2007, pp. 122 - 127.
[24] C. F. v. Carmer, A. C. Rummel, G. H. Jirka, "Mass transport in shallow
turbulent wake flow by planar concentration analysis technique". J. of
Hyd. Eng. vol. 135, no.4, pp. 257 - 270, 2009
[25] D. Chen, C. Chen, F. E. Tang, P. Stansby, M. Li, "Boundary Layer
Structure of Oscillatory Open-Channel Shallow Flows over Smooth and
Rough Beds", Experiments in Fluids, vol. 42, no. 5, pp. 719-736, 2007
[26] P. M. Lloyd, P. K. Stansby, D. Chen, "Wake formation around islands in
oscillatory laminar shallow-water flows", J. of Fluid Mechanics, vol.
429, 2001
[27] P. M. Lloyd, P. K. Stansby, "Shallow-water flow around model conical
islands of small side slope. I: surface piercing", J. of Hyd. Eng., vol. 23,
no. 12, pp. 1057-1068, 1997
[28] F. E. Tang, "Visualization of tidal flow near a coastal headland", Proc.
Of the Marine Waste Water Discharge (MWWD) Conf. 2010, Langkawi,
Malaysia, 2010
[29] J. F. A. Sleath, "Turbulent oscillatory flow over rough beds", J. of Fluid
Mechanics, vol. 182, 1987
[30] P. N. Papanicolaou, E. J. List, "Investigations of round vertical turbulent
buoyant jets". J. of Fluid Mechanics, vol. 209, pp. 151 - 190, 1988
[31] Chen, D., Jirka, G.H., "Pollutant mixing in wake flows behind islands in
shallow water", in Proc. of the Int. Symp. on Environmental Hydraulics,
Hong Kong, 1991, pp. 371-377.
[32] Chen, D., Jirka, G.H., "LIF study of plane jet bounded in shallow water
layer", J. of Hyd. Eng. vol. 125, no. 8, pp. 817-826, 1999
[33] D. G. MacDonald, G. H. Jirka, "Characteristics of headland wakes in
shallow flow", In Proc. of the Congress of the IAHR, Netherlands, 1997,
pp. 88 - 93.
[34] L. P. Xia, K. M. Lam, "Velocity and concentration measurements in
initial region of submerged round jets in stagnant environment and in
coflow", J. of Hydro-Environment Res., vol. 3, no. 1, pp. 21-34, 2009
[35] J.W. Kamphuis, "Friction factor under oscillatory waves". J. of the
waterways, harbors and coastal eng. div. vol. 101, no. WW2, 1975
[36] P.M. Lloyd, P.K. Stansby, D. Chen, R.A. Falconer, J. Yin, Y. Chen,
"Eddy formation around a conical headland in oscillatory shallow-water
flow". Private communication, 2004
[1] D., Chen, F. E. Tang, C. Chen, "PLIF study of pollutant trapping and 3-
D plume structures in recirculation zones around a headland: steady and
tidal currents", In Proc. of the Int. Symp. on Shallow Flows, ASCE,
Holland, 2003
[2] D. Chen, F. E. Tang, C. Chen, "Pollutant trapping at a coastal headland",
J. of Waterway, Port, Coastal and Ocean Eng., vol. 131, no. 3, pp. 98-
114, 2005
[3] L. Loubersac, "Application of high resolution satellite data in the
observation of coastal environment. The case of SPOT simulations
within the framework of ecological survey of Brittany coasts". Special
publication, European Space Agency, 1983
[4] R. D. Pingree, G. T. Mardell, L. Maddock, "Tidal mixing in the channel
isles region derived from the results of remote sensing and
measurements at sea". Estuarine, Coastal and Shelf Science, vol. 20, pp.
1 - 18, 1985
[5] T. F. Duda, and C. S. Cox, "Vorticity measurement in a region of coastal
ocean eddies by observation of near inertial oscillations", Geophys. Res.
Lett., vol. 14, no. 8, pp. 793-796, 1987
[6] P. A. Davies, L. A. Mofor, "Observations of flow separation by an
isolated island". Int. J. of Remote Sensing, vol. 11, no.5, 1990
[7] W. R. Geyer, R. Signell, "Measurements of tidal flow around a headland
with a shipboard acoustic doppler current profiler". J. of Geophys. Res.,
vol. 95, no. C3, 1990
[8] M. Gade, W. Alpers, "Using ERS2-SAR images for routine observation
of marine pollution in European coastal waters". The Sci. of the Total
Environment. vol. 237/238, pp. 441 - 448, 1999
[9] Q. Y. Zhang, 2006. "Comparison of two three-dimensional
hydrodynamic modeling systems for coastal tidal motion". Ocean Eng.
vol. 33. pp. 137 - 151, 2006
[10] P. L. Murphy, A. Valle-Levinson, "Tidal and residual circulation in the
St. Andrew Bay system, Florida". Continental Self Research, vol. 28. pp.
2678 - 2688, 2008
[11] Y. Coeffe, S. Courtier, B. Latteux, "Tidal sea mathematical modeling:
current applications and future developments". Coastal Eng., vol. 11, pp.
479 - 511, 1987
[12] R. A. Falconer, E. Wolanski, L. Mardapitta Hadjipandeli, "Modelling
tidal circulation in an island-s wake". J. of Waterway, Port, Coastal and
Ocean Eng., vol. 112, Iss. 2, pp. 234-254, 1986
[13] R. A. Falconer, L. Mardapitta Hadjipandeli, "Bathymetric and shear
stress effects on an island-s wake: a computational model study".
Coastal Eng., vol. 11, pp. 57 - 86, 1987
[14] R. P. Signell, W. R. Geyer, 1991. "Transient eddy formation around
headlands". J. of Geophys. Res., vol. 96, no. C2, 1991
[15] D. Galloway, E. Wolanski, B. King, "Modelling eddy formations in
coastal waters: A comparison between model capabilities". Proc. of the
conf. on Estuarine and Coastal Modelling, 1995, pp. 13 - 25.
[16] S. A. Socolofsky, G. H. Jirka, "Large-scale flow structures and stability
in shallow flows". J. of Environmental Eng. Sci. vol. 3, Iss. 5, pp. 451 -
462, 2004
[17] G. H. Jirka, "Large-scale flow structures and mixing processes in
shallow flows". J. of Hyd. Res. vol. 39, Iss. 6, pp. 567 - 573, 2001
[18] C. Dong, J. C. McWilliams, "A numerical study of island wakes in the
Southern California Bight", Continental Shelf Research, vol. 27, no. 9, pp.
1233-1248, 2007
[19] M. J. Alaee, C. Pattiaratchi, G. Ivey, "Numerical simulation of the
summer wake of Rottnest Island, Western Australia", Dynamics of
Atmospheres and Oceans, vol. 43, no. 3-4, pp. 171-198, 2007
[20] I. M. Brooks, S. Soderberg, M. Tjernstrom, "The turbulence structure of
the stable atmospheric boundary layer around a coastal headland: aircraft
observations and modeling results", Boundary Layer Meteorology, vol.
107, pp. 531-559, 2003
[21] P. F. Coutis, J. H. Middleton, "The physical and biological impact of a
small island wake in the deep ocean". Deep Sea Research I. vol. 49, pp.
1341 - 1361, 2002
[22] O. Leuchter, J. L. Solignac, "Experimental investigation of the turbulent
structure of vortex wakes". Proc. of the 4th Int. Symp. on Turbulent
Shear Flows, 1985, pp. 156 - 168.
[23] P. Menzel, F. Huttmann, M. Brede, A. Leder, "Experimental
investigations of mixing processes in the wake of a circular cylinder in
stratified flows". Proc. of the Conf. on Multiphase flow: The Ultimate
Measurement Challenge, 2007, pp. 122 - 127.
[24] C. F. v. Carmer, A. C. Rummel, G. H. Jirka, "Mass transport in shallow
turbulent wake flow by planar concentration analysis technique". J. of
Hyd. Eng. vol. 135, no.4, pp. 257 - 270, 2009
[25] D. Chen, C. Chen, F. E. Tang, P. Stansby, M. Li, "Boundary Layer
Structure of Oscillatory Open-Channel Shallow Flows over Smooth and
Rough Beds", Experiments in Fluids, vol. 42, no. 5, pp. 719-736, 2007
[26] P. M. Lloyd, P. K. Stansby, D. Chen, "Wake formation around islands in
oscillatory laminar shallow-water flows", J. of Fluid Mechanics, vol.
429, 2001
[27] P. M. Lloyd, P. K. Stansby, "Shallow-water flow around model conical
islands of small side slope. I: surface piercing", J. of Hyd. Eng., vol. 23,
no. 12, pp. 1057-1068, 1997
[28] F. E. Tang, "Visualization of tidal flow near a coastal headland", Proc.
Of the Marine Waste Water Discharge (MWWD) Conf. 2010, Langkawi,
Malaysia, 2010
[29] J. F. A. Sleath, "Turbulent oscillatory flow over rough beds", J. of Fluid
Mechanics, vol. 182, 1987
[30] P. N. Papanicolaou, E. J. List, "Investigations of round vertical turbulent
buoyant jets". J. of Fluid Mechanics, vol. 209, pp. 151 - 190, 1988
[31] Chen, D., Jirka, G.H., "Pollutant mixing in wake flows behind islands in
shallow water", in Proc. of the Int. Symp. on Environmental Hydraulics,
Hong Kong, 1991, pp. 371-377.
[32] Chen, D., Jirka, G.H., "LIF study of plane jet bounded in shallow water
layer", J. of Hyd. Eng. vol. 125, no. 8, pp. 817-826, 1999
[33] D. G. MacDonald, G. H. Jirka, "Characteristics of headland wakes in
shallow flow", In Proc. of the Congress of the IAHR, Netherlands, 1997,
pp. 88 - 93.
[34] L. P. Xia, K. M. Lam, "Velocity and concentration measurements in
initial region of submerged round jets in stagnant environment and in
coflow", J. of Hydro-Environment Res., vol. 3, no. 1, pp. 21-34, 2009
[35] J.W. Kamphuis, "Friction factor under oscillatory waves". J. of the
waterways, harbors and coastal eng. div. vol. 101, no. WW2, 1975
[36] P.M. Lloyd, P.K. Stansby, D. Chen, R.A. Falconer, J. Yin, Y. Chen,
"Eddy formation around a conical headland in oscillatory shallow-water
flow". Private communication, 2004
@article{"International Journal of Earth, Energy and Environmental Sciences:51723", author = "Fu E. Tang and Daoyi Chen", title = "Tidal Flow Patterns Near A Coastal Headland", abstract = "Experimental investigations were carried out in the
Manchester Tidal flow Facility (MTF) to study the flow patterns in
the region around and adjacent to a hypothetical headland in tidal
(oscillatory) ambient flow. The Planar laser-induced fluorescence
(PLIF) technique was used for visualization, with fluorescent dye
released at specific points around the headland perimeter and in its
adjacent recirculation zone. The flow patterns can be generalized into
the acceleration, stable flow and deceleration stages for each halfcycle,
with small variations according to location, which are more
distinct for low Keulegan-Carpenter number (KC) cases. Flow
patterns in the mixing region are unstable and complex, especially in
the recirculation zone. The flow patterns are in agreement with
previous visualizations, and support previous results in steady
ambient flow. It is suggested that the headland lee could be a viable
location for siting of pollutant outfalls.", keywords = "Planar laser-induced Fluorescence, recirculation
zone, tidal flow, wake flows", volume = "6", number = "3", pages = "110-9", }
