Nishino, et al., 2015. |
Nishino, S. et al., 2015. Nutrient supply and biological response to wind-induced mixing, inertial motion, internal waves, and currents in the northern Chukchi Sea. Journal of Geophysical Research: Oceans, 120(3), pp.1975–1992. |
Show on map |
Cudaback & McPhee-Shaw, 2009. |
Cudaback, C.N. & McPhee-Shaw, E., 2009. Diurnal-period internal waves near point conception, California. Estuarine, Coastal and Shelf Science, 83(3), pp.349–359. |
Show on map |
Cacchione & Pratson, 2004 |
Cacchione, D. A., & Pratson, L. F. 2004. Internal tides and the continental slope: Curious waves coursing beneath the surface of the sea may shape the margins of the world's landmasses. American scientist, 92(2), pp 130-137. |
Show on map |
Davidson & Holloway, 2003. |
Davidson, F.J.M. & Holloway, P. E., 2003. A study of tropical cyclone influence on the generation of internal tides. Journal of Geophysical Research, 108(C3). |
Show on map |
Shay, et al., 1990. |
Shay, L. K., Chang, S. W., & Elsberry, R. L., 1990. Free surface effects on the near-inertial ocean current response to a hurricane. Journal of physical oceanography, 20(9), 1405-1424. |
Show on map |
Hingsamer, 2014 |
Hingsamer, P., Peeters, F. and Hofmann, H. 2014. The consequences of internal waves for phytoplankton focusing on the distribution and production of Planktothrix rubescens, PloS one, 9(8), p. e104359. |
Show on map |
Krechik, 2019 |
Krechik, V., Myslenkov, S. and Kapustina, M. 2019. New possibilities in the study of coastal upwellings in the southeastern Baltic sea with using thermistor chain, GEOGRAPHY ENVIRONMENT SUSTAINABILITY, 12(2), pp. 44–61. doi: 10.24057/2071-9388-2018-67. |
Show on map |
Cao, 2010 |
Cao, A., Guo, Z., Pan, Y., Song, J., He, H. and Li, P., 2021. Near-Inertial Waves Induced by Typhoon Megi (2010) in the South China Sea. Journal of Marine Science and Engineering, 9(4), p.440.
https://doi.org/10.3390/jmse9040440 |
Show on map |
Lee, S, 2021 |
Lee, S.-W. and Nam, S. (2021) “Estimation of propagation speed and direction of nonlinear internal waves from underway and moored measurements,” Journal of marine science and engineering, 9(10), p. 1089. doi: 10.3390/jmse9101089. |
Show on map |
Zhang, 2021 |
Zhang, Z., Chen, X. and Pohlmann, T. (2021) “The impact of fortnightly stratification variability on the generation of baroclinic tides in the Luzon Strait,” Journal of marine science and engineering, 9(7), p. 703. doi: 10.3390/jmse9070703. |
Show on map |
Li, 2022 |
Li, J. et al. (2022) “Noise of internal solitary waves measured by mooring-mounted hydrophone array in the South China Sea,” Journal of marine science and engineering, 10(2), p. 222. doi: 10.3390/jmse10020222. |
Show on map |
Wang, 2022 |
Wang, T. et al. (2022) “Internal solitary wave activities near the Indonesian submarine wreck site inferred from satellite images,” Journal of marine science and engineering, 10(2), p. 197. doi: 10.3390/jmse10020197. |
Show on map |
Liang, 2022 |
Liang, J., Li, X.-M. and Fan, K. (2022) “Distribution and source sites of nonlinear internal waves northeast of Hainan Island,” Journal of marine science and engineering, 10(1), p. 55. doi: 10.3390/jmse10010055. |
Show on map |
Noh, 2021 |
Noh, S. and Nam, S. (2021) “Nonseasonal variations in near-inertial kinetic energy observed far below the surface mixed layer in the southwestern East Sea (japan sea),” Journal of marine science and engineering, 10(1), p. 9. doi: 10.3390/jmse10010009. |
Show on map |
Xu, 2021 |
Xu, A. and Chen, X. (2021) “A strong internal solitary wave with extreme velocity captured northeast of Dong-Sha Atoll in the northern South China Sea,” Journal of marine science and engineering, 9(11), p. 1277. doi: 10.3390/jmse9111277. |
Show on map |