Kuroshio Meanders in the East China Sea

Charles James Graduate School of Oceanography, University of Rhode Island, Narragansett, Rhode Island

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Mark Wimbush Graduate School of Oceanography, University of Rhode Island, Narragansett, Rhode Island

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Hiroshi Ichikawa Faculty of Fisheries, Kagoshima University, Kagoshima, Japan

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Abstract

An array of seven inverted echo sounders was moored along and across the Kuroshio in the East China Sea for more than one year. The data from this array show evidence of energetic meanders with periods of 7, 11, and 16 days. The respective phase velocities of these meanders are 28, 20, and 17 km day−1 downstream. The 7- and 16-day waves are intermittent, but the 11-day waves are present throughout the deployment.

The instability responsible for these waves is investigated with a spectral numerical model applied to a background state representing the Kuroshio in this region. The fastest-growing instability from the model has e-folding growth time of 2 days, period of 12 days, and phase velocity of 18 km day−1 downstream. It appears to be a close representation of the 11-day wave seen in the observational data.

Such a model has been previously used to represent meanders in the Gulf Stream at similar latitudes off the east coast of the United States. The Kuroshio meanders have approximately half the phase velocity and twice the period of the Gulf Stream meanders. To investigate the reasons for these differences, the flow and topography of the model background state were varied. The slower phase velocity and longer period of the Kuroshio meanders appear to be consequences of the deeper shelf and lower transport, with a modifying effect due to the difference in cross-shelf positioning of the current core (more over-the-shelf in the case of the Kuroshio).

* Current affiliation: School of Earth Sciences, Flinders University of South Australia, Adelaide, South Australia.

Corresponding author address: Dr. Charles James, FIAMS, School of Earth Sciences, Flinders University of South Australia, GPO Box 2100, Adelaide, South Australia 5001.

Abstract

An array of seven inverted echo sounders was moored along and across the Kuroshio in the East China Sea for more than one year. The data from this array show evidence of energetic meanders with periods of 7, 11, and 16 days. The respective phase velocities of these meanders are 28, 20, and 17 km day−1 downstream. The 7- and 16-day waves are intermittent, but the 11-day waves are present throughout the deployment.

The instability responsible for these waves is investigated with a spectral numerical model applied to a background state representing the Kuroshio in this region. The fastest-growing instability from the model has e-folding growth time of 2 days, period of 12 days, and phase velocity of 18 km day−1 downstream. It appears to be a close representation of the 11-day wave seen in the observational data.

Such a model has been previously used to represent meanders in the Gulf Stream at similar latitudes off the east coast of the United States. The Kuroshio meanders have approximately half the phase velocity and twice the period of the Gulf Stream meanders. To investigate the reasons for these differences, the flow and topography of the model background state were varied. The slower phase velocity and longer period of the Kuroshio meanders appear to be consequences of the deeper shelf and lower transport, with a modifying effect due to the difference in cross-shelf positioning of the current core (more over-the-shelf in the case of the Kuroshio).

* Current affiliation: School of Earth Sciences, Flinders University of South Australia, Adelaide, South Australia.

Corresponding author address: Dr. Charles James, FIAMS, School of Earth Sciences, Flinders University of South Australia, GPO Box 2100, Adelaide, South Australia 5001.

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  • Bane, J. M., and D. A. Brooks, 1979: Gulf Stream meanders along the continental margin from the Florida Straits to Cape Hatteras. Geophys. Res. Lett.,6, 280–282.

  • Bingham, C., M. Godfrey, and J. Tukey, 1967: Modern techniques of power spectrum estimation. IEEE Trans. Audio Electroacoust.,AU-15, 56–66.

  • Chen, C., R. C. Beardsley, and R. Limeburner, 1992: The structure of the Kuroshio southwest of Kyushu: velocity, transport and potential vorticity fields. Deep-Sea Res.,39, 245–268.

  • Ichikawa, H., 1993: Short period variations of the Kuroshio volume transport in the East China Sea. Umi to Sora,69, 135–148.

  • ——, and R. C. Beardsley, 1993: Temporal and spatial variability of volume transport of the Kuroshio in the East China Sea. Deep-Sea Res.,40, 583–605.

  • James, C., 1996: Kuroshio instabilities in the East China Sea—Observations, modeling, and comparison with the Gulf Stream. Ph.D. thesis, University of Rhode Island, 150 pp.

  • ——, and M. Wimbush, 1995: Inferring dynamic height variations from acoustic travel time in the Pacific Ocean. J. Oceanogr.,51, 553–569.

  • ——, ——, and H. Ichikawa, 1994: East China Sea, Kuroshio 1991–92 data report, Graduate School of Oceanography Tech. Rep. 94-3, 22 pp. [Available from Graduate School of Oceanography, University of Rhode Island, Narragansett, RI 02882.].

  • Kaneko, A., W. Koterayama, H. Honji, S. Mizuno, K. Kawatate, and R. Gordon, 1990: Cross-stream survey of the upper 400 m of the Kuroshio by an ADCP on a towed fish. Deep-Sea Res.,37, 875–889.

  • ——, N. Gohda, W. Koterayama, M. Nakamura, S. Mizuno, and H. Furukawa, 1993: Towed ADCP fish with depth and roll controllable wings and its application to the Kuroshio observation. J. Oceanogr.,49, 383–395.

  • Kontoyiannis, H., and D. R. Watts, 1994: Observations on the variability of the Gulf Stream path between 74°W and 70°W. J. Phys. Oceanogr.,24, 1999–2013.

  • Lee, T. N., and L. P. Atkinson, 1983: Low-frequency current and temperature variability from Gulf Stream frontal eddies and atmospheric forcing along the southeast U.S. outer continental shelf. J. Geophys. Res.,88, 4541–4567.

  • Moore, G. W. K., and W. R. Peltier, 1987: Cyclogenesis in frontal zones. J. Atmos. Sci.,44, 384–409.

  • Orlanski, I., 1969: The influence of bottom topography on the stability of jets in a baroclinic fluid. J. Atmos. Sci.,26, 1216–1232.

  • Pedlosky, J., 1964: The stability of currents in the atmosphere and the ocean: Part I. J. Atmos. Sci.,21, 201–219.

  • Preisendorfer, R. W., 1988: Principal Component Analysis in Meteorology and Oceanography. Elsevier, 425 pp.

  • Qiu, B., T. Toda, and N. Imasato, 1990: On Kuroshio front fluctuations in the East China Sea using satellite and in situ observational data. J. Geophys. Res.,95, 18 191–18 203.

  • Richardson, W. S., W. J. Schmitz, and P. N. Niiler, 1969: The velocity structure of the Florida Current from the Straits of Florida to Cape Fear. Deep-Sea Res.,16 (Suppl.), 225–231.

  • Sugimoto, Y., S. Kimura, and K. Miyaji, 1988: Meander of the Kuroshio front and current variability in the East China Sea. J. Oceanogr. Soc. Japan,44, 125–135.

  • Sun, X.-P., and Y.-F. Su, 1994: On the variation of Kuroshio in East China Sea. Oceanology of China Seas, D. Zhou, Y.-B. Liang, and C. K. Tseng, Eds., Vol. 1, Kluwer Academic, 49–58.

  • Trivers, G., and M. Wimbush, 1994: Using acoustic travel time to determine dynamic height variations in the North Atlantic Ocean. J. Atmos. Oceanic Technol.,11, 1309–1316.

  • Wallace, J. M., and R. E. Dickinson, 1972: Empirical orthogonal representation of time series in the frequency domain. Part I: Theoretical considerations. J. Appl. Meteor.,11, 887–892.

  • Watts, D. R., and H. T. Rossby, 1977: Measuring dynamic heights with inverted echo sounders: Results from MODE. J. Phys. Oceanogr.,7, 345–358.

  • Xue, H., 1991: Numerical studies of Gulf Stream meanders in the South Atlantic Bight. Ph.D. thesis, Princeton University, 188 pp.

  • ——, and G. Mellor, 1993: Instability of the Gulf Stream front in the South Atlantic Bight. J. Phys. Oceanogr.,23, 2326–2350.

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