The Effects of Wind Forcing on Surface Currents on the Continental Shelf Surrounding Rottnest Island
Surface currents play a major role in the distribution
of contaminants, the connectivity of marine populations, and can
influence the vertical and horizontal distribution of nutrients within
the water column. This paper aims to determine the effects of sea
breeze-wind patterns on the climatology of the surface currents on the
continental shelf surrounding Rottnest Island, WA Australia. The
alternating wind patterns allow for full cyclic rotations of wind
direction, permitting the interpretation of the effect of the wind on the
surface currents. It was found that the surface currents only clearly
follow the northbound Capes Current in times when the Fremantle
Doctor sets in. Surface currents react within an hour to a change of
direction of the wind, allowing southerly currents to dominate during
strong northerly sea breezes, often followed by mixed currents
dominated by eddies in the inter-lying times.
[1] Feng, M., Meyers, G., Pearce, A., Wijffels, S., 2003. Annual and
interannual variations of the Leeuwin Current at 32degrees South.
Journal of Geophysical Research, Vol. 108, No. C11, 3355, doi:
10.1029/2002JC001763.
[2] GOOS (global ocean observing system), 2011;
(http://gosic.org/ios/MATRICES/ECV/OCEAN/SURFACE/ECVGCOS-
OCEAN-SURFACE-current.htm).
[3] Gurgel, K.W., Antonischki, G., Essen, H.H., Schlick, T., 2000. Wellen
Radar (WERA): a new ground-wave HF radar for ocean remote sensing.
(www:http://ifmaxp1.ism.uni-hamburg.de/scawvex.htmlx).
[4] Halverson, M.J., Ohlmann, J.C., Johnson, M.A., Pegau, W.S., 2011.
Disruption of a cyclonic eddy circulation by wind stress in Prince
William Sound,Alaska, Continental Shelf Research,
doi:10.1016/j.csr.2011.12.002.
[5] Inman, D.L. and Filloux, J., 1960. Beach cycle related to the tide and
local wind regime. Journal of Geology, 68, 225,231.
[6] Largier J. L. 2003. Considerations in estimating larval dispersal
distances from oceanographic data. Ecol. Appl. Vol. 13, pp. 71-89.
[7] Masselink, G. and Pattiaratchi, C.B., 1998a. Morphodynamic impact of
sea breeze activity on a beach with cusp morphology. Journal of Coastal
Research, 14(2), 393-409.
[8] Masselink, G., and Pattiaratchi, C.B., 2001a. Characteristics of the sea
breeze system in Perth Western Australia, and its effect on the near
shore wave climate. Journal of Coastal Research, 17(1), 173-187.
[9] Paduan, J.D., Graber, H.C., 1997. Introduction to High-Frequency
Radar: Reality and Myth. Oceanography, Vol. 10, No. 2, pp. 36-39.
[10] Pattiaratchi, C., Hegge, B., Gould, J. and Eliot, I., 1997. Impact of seabreeze
activity on nearshore and foreshore processes in southwestern
Australia. Continental Shelf Research, 17(13), 1539-1560.
[11] Pearce, A.F., Griffiths, R.W., 1991. The Mesoscale Structure of the
Leeuwin Current: A Comparison of Laboratory Models and Satellite
Imagery. Journal of Geophysical Research, Vol. 96, No. C9, pp. 16,739-
16,757, doi: 10.1029/91JC01712.
[12] Rao, R.R., Molinari, R.L., Festa, J.F., 1989. Evolution of the
Climatological Near-Surface Thermal Structure of the Tropical Indian
Ocean. 1. Description of Mean Monthly Mixed Layer Depth, and Sea
Surface Temperature, Surface Current, and Surface Meteorological
Fields. Journal of Geophysical Research, Vol. 94, Mo. C8, pp 10,801 -
10,815.
[13] Sentchev, A., Forget, P., Barbin, Y., Yaremchuk, M., Surface circulation
in the Iroise Sea (W. Brittany) from high resolution HF, article in press.
[14] Weersing K., Toonen R. J. 2009. Population genetics, larval dispersal,
and connectivity in marine systems. Mar. Ecol. Prog. Ser. 393, 1-12.
[15] White, C., Selkoe, K.A., Watson, J., Siegel, D.A., Zacherl, D.C.,
Toonen, R.J., 2010. Ocean currents help explain population genetic
structure. Proceedings of the Royal Society, Biological Sciences, Vol.
277, pp. 1685-1694. Doi: 10.1098/rspb.2009.2214.
[1] Feng, M., Meyers, G., Pearce, A., Wijffels, S., 2003. Annual and
interannual variations of the Leeuwin Current at 32degrees South.
Journal of Geophysical Research, Vol. 108, No. C11, 3355, doi:
10.1029/2002JC001763.
[2] GOOS (global ocean observing system), 2011;
(http://gosic.org/ios/MATRICES/ECV/OCEAN/SURFACE/ECVGCOS-
OCEAN-SURFACE-current.htm).
[3] Gurgel, K.W., Antonischki, G., Essen, H.H., Schlick, T., 2000. Wellen
Radar (WERA): a new ground-wave HF radar for ocean remote sensing.
(www:http://ifmaxp1.ism.uni-hamburg.de/scawvex.htmlx).
[4] Halverson, M.J., Ohlmann, J.C., Johnson, M.A., Pegau, W.S., 2011.
Disruption of a cyclonic eddy circulation by wind stress in Prince
William Sound,Alaska, Continental Shelf Research,
doi:10.1016/j.csr.2011.12.002.
[5] Inman, D.L. and Filloux, J., 1960. Beach cycle related to the tide and
local wind regime. Journal of Geology, 68, 225,231.
[6] Largier J. L. 2003. Considerations in estimating larval dispersal
distances from oceanographic data. Ecol. Appl. Vol. 13, pp. 71-89.
[7] Masselink, G. and Pattiaratchi, C.B., 1998a. Morphodynamic impact of
sea breeze activity on a beach with cusp morphology. Journal of Coastal
Research, 14(2), 393-409.
[8] Masselink, G., and Pattiaratchi, C.B., 2001a. Characteristics of the sea
breeze system in Perth Western Australia, and its effect on the near
shore wave climate. Journal of Coastal Research, 17(1), 173-187.
[9] Paduan, J.D., Graber, H.C., 1997. Introduction to High-Frequency
Radar: Reality and Myth. Oceanography, Vol. 10, No. 2, pp. 36-39.
[10] Pattiaratchi, C., Hegge, B., Gould, J. and Eliot, I., 1997. Impact of seabreeze
activity on nearshore and foreshore processes in southwestern
Australia. Continental Shelf Research, 17(13), 1539-1560.
[11] Pearce, A.F., Griffiths, R.W., 1991. The Mesoscale Structure of the
Leeuwin Current: A Comparison of Laboratory Models and Satellite
Imagery. Journal of Geophysical Research, Vol. 96, No. C9, pp. 16,739-
16,757, doi: 10.1029/91JC01712.
[12] Rao, R.R., Molinari, R.L., Festa, J.F., 1989. Evolution of the
Climatological Near-Surface Thermal Structure of the Tropical Indian
Ocean. 1. Description of Mean Monthly Mixed Layer Depth, and Sea
Surface Temperature, Surface Current, and Surface Meteorological
Fields. Journal of Geophysical Research, Vol. 94, Mo. C8, pp 10,801 -
10,815.
[13] Sentchev, A., Forget, P., Barbin, Y., Yaremchuk, M., Surface circulation
in the Iroise Sea (W. Brittany) from high resolution HF, article in press.
[14] Weersing K., Toonen R. J. 2009. Population genetics, larval dispersal,
and connectivity in marine systems. Mar. Ecol. Prog. Ser. 393, 1-12.
[15] White, C., Selkoe, K.A., Watson, J., Siegel, D.A., Zacherl, D.C.,
Toonen, R.J., 2010. Ocean currents help explain population genetic
structure. Proceedings of the Royal Society, Biological Sciences, Vol.
277, pp. 1685-1694. Doi: 10.1098/rspb.2009.2214.
@article{"International Journal of Earth, Energy and Environmental Sciences:61731", author = "Jennifer Penton and Charitha Pattiaratchi", title = "The Effects of Wind Forcing on Surface Currents on the Continental Shelf Surrounding Rottnest Island", abstract = "Surface currents play a major role in the distribution
of contaminants, the connectivity of marine populations, and can
influence the vertical and horizontal distribution of nutrients within
the water column. This paper aims to determine the effects of sea
breeze-wind patterns on the climatology of the surface currents on the
continental shelf surrounding Rottnest Island, WA Australia. The
alternating wind patterns allow for full cyclic rotations of wind
direction, permitting the interpretation of the effect of the wind on the
surface currents. It was found that the surface currents only clearly
follow the northbound Capes Current in times when the Fremantle
Doctor sets in. Surface currents react within an hour to a change of
direction of the wind, allowing southerly currents to dominate during
strong northerly sea breezes, often followed by mixed currents
dominated by eddies in the inter-lying times.", keywords = "HF radar, surface currents, sea breeze.", volume = "7", number = "1", pages = "49-6", }
