Short description Full description
Wang et al., 2020 Wang, J., Wang, T., Xing, F., Wu, H., Jia, J., Yang, Z., & Wang, Y. P., 2020. Internal waves triggered by river mouth shoals in the Yangtze River Estuary. Ocean Engineering, 214, p.107828. Show on map
Zhang et al., 2019 Zhang, H., Ma, X., Zhuang, L., & Yan, J., 2019. Sand waves near the shelf break of the northern South China Sea: morphology and recent mobility. Geo-Marine Letters, 39(1), pp.19–36. Show on map
Villacieros‐Robineau et al., 2019 Villacieros‐Robineau, N., Zúñiga, D., Barreiro‐González, B., Alonso‐Pérez, F., de la Granda, F., Froján, M., Collins C. A., Barton E. D. & Castro, C. G., 2019. Bottom Boundary Layer and Particle Dynamics in an Upwelling Affected Continental Margin (NW Iberia). Journal of Geophysical Research: Oceans, 124(12), pp.9531–9552. Show on map
Garwood et al., 2020 Garwood, J. C., Lucas, A. J., Naughton, P., Alford, M. H., Roberts, P. L., Jaffe, J. S., deGelleke L. & Franks, P. J., 2020. A novel cross‐shore transport mechanism revealed by subsurface, robotic larval mimics: Internal wave deformation of the background velocity field. Limnology and Oceanography, 65(7), pp.1456–1470. Show on map
Gough et al., 2020 Gough, M. K., Freismuth, T. M., MacMahan, J. H., Colosi, J. A., Suanda, S. H., & Kumar, N., 2020. Heating of the Midshelf and Inner Shelf by Warm Internal Tidal Bores. Journal of Physical Oceanography, 50(9), pp.2609–2620. Show on map
Thomson & Spear, 2020 Thomson, R.E. & Spear, D.J., 2020. Gravity Currents Facilitate Formation of High‐Frequency Internal Solitons and Bores at the Base of the Fraser Delta in the Southern Strait of Georgia. Journal of Geophysical Research: Oceans, 125(10). Show on map
Yang et al., 2020 Yang, W., Wei, H., Zhao, L., & Zhang, J., 2020. Turbulence and vertical nitrate flux adjacent to the Changjiang Estuary during fall. Journal of Marine Systems, 212, p.103427. Show on map
Jithin et al., 2020 Jithin, A. K., Subeesh, M. P., Francis, P. A., & Ramakrishna, S. S., 2020. Intensification of tidally generated internal waves in the north-central Bay of Bengal. Scientific Reports, 10(1). Show on map
Chitamwebwa, 1999 Chitamwebwa, D.B.R., 1999. Meromixis, stratification and internal waves in Kigoma waters of Lake Tanganyika. From Limnology to Fisheries: Lake Tanganyika and Other Large Lakes, pp.59–64. Show on map
McPherson et al., 2020 McPherson, R. A., Stevens, C. L., O'Callaghan, J. M., Lucas, A. J., & Nash, J. D., 2020. The role of turbulence and internal waves in the structure and evolution of a near-field river plume. Ocean Science, 16(4), pp.799–815. Show on map
Kawaguchi et al., 2020 Kawaguchi, Y., Wagawa, T. & Igeta, Y., 2020. Near-inertial internal waves and multiple-inertial oscillations trapped by negative vorticity anomaly in the central Sea of Japan. Progress in Oceanography, 181, p.102240. Show on map
Khimchenko et al., 2020 Khimchenko, E.E., Frey, D.I. & Morozov, E.G., 2020. Tidal internal waves in the Bransfield Strait, Antarctica. Russian Journal of Earth Sciences, 20(2), pp.1–6. Show on map
Svergun & Zimin, 2020 Svergun, E. I., & Zimin, A. V., 2020. Characteristics of Short-Period Internal Waves in the Avacha Bay Based on the In Situ and Satellite Observations in August-September, 2018. Morskoy gidrofizicheskiy zhurnal, 36(3). Show on map
Tiemann et al., 2001 Tiemann, C.O., Worcester, P.F. & Cornuelle, B.D., 2001. Acoustic scattering by internal solitary waves in the Strait of Gibraltar. The Journal of the Acoustical Society of America, 109(1), pp.143–154. Show on map
Kinder, 1984 Kinder, T.H., 1984. Net mass transport by internal waves near the Strait of Gibraltar. Geophysical Research Letters, 11(10), pp.987–990. Show on map