| Serebryany, A., 2022 |
Serebryany, A., Khimchenko, E., Zamshin, V., & Popov, O. (2022). Features of the Field of Internal Waves on the Abkhazian Shelf of the Black Sea according to Remote Sensing Data and In Situ Measurements. Journal of Marine Science and Engineering, 10(10), 1342. |
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| Khimchenko, E., 2022 |
Khimchenko, E., Ostrovskii, A., Klyuvitkin, A., & Piterbarg, L. (2022). Seasonal variability of near-inertial internal waves in the deep central part of the Black Sea. Journal of Marine Science and Engineering, 10(5), 557. |
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| Jiang, Y., 2022 |
Jiang, Y., Grigorev, V., & Katsnelson, B. (2022). Sound field fluctuations in shallow water in the presence of moving nonlinear internal waves. Journal of Marine Science and Engineering, 10(1), 119. |
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| Tao, M., 2022 |
Tao, M., Xu, C., Guo, L., Wang, X., & Xu, Y. (2022). An Internal Waves Data Set From Sentinel‐1 Synthetic Aperture Radar Imagery and Preliminary Detection. Earth and Space Science, 9(12), e2022EA002528. |
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| Svergun, E. I., 2022 |
Svergun, E. I., Zimin, A. V., & Zhegulin, G. V. (2022). Observations of the Second Mode Internal Waves in the White and Barents Seas. Physical Oceanography, 29(2), 172-181. |
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| Endoh, T., 2022 |
Endoh, T., Tsutsumi, E., Hong, C. S., Baek, G. N., Chang, M. H., Yang, Y. J., ... & Lee, J. H. (2022). Estimating propagation speed and direction, and vertical displacement of second-mode nonlinear internal waves from ADCP measurements. Continental Shelf Research, 233, 104644. |
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| Sinnett, G., 2022 |
Sinnett, G., Ramp, S. R., Yang, Y. J., Chang, M. H., Jan, S., & Davis, K. A. (2022). Large-amplitude internal wave transformation into shallow water. Journal of Physical Oceanography, 52(10), 2539-2554. |
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| van Haren, H., 2022 |
van Haren, H., Voet, G., Alford, M. H., & Torres, D. J. (2022). Internal wave breaking near the foot of a steep East-Pacific continental slope. Progress in Oceanography, 205, 102817. |
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| Liu, H., 2022 |
Liu, H., Yang, W., Wei, H., Jiang, C., Liu, C., & Zhao, L. (2022). On characteristics and mixing effects of internal solitary waves in the northern Yellow Sea as revealed by satellite and in situ observations. Remote Sensing, 14(15), 3660. |
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| Zhang, H., 2022 |
Zhang, H., Meng, J., Sun, L., & Li, S. (2022). Observations of Reflected Internal Solitary Waves near the Continental Shelf of the Dongsha Atoll. Journal of Marine Science and Engineering, 10(6), 763. |
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| Hou, H., 2022 |
Hou, H., Xu, T., Li, B., Yang, B., Wei, Z., & Yu, F. (2022). Different types of near-inertial internal waves observed by lander in the intermediate-deep layers of the South China Sea and their generation mechanisms. Journal of Marine Science and Engineering, 10(5), 594. |
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| Huang, L., 2023 |
Huang, L., Yang, J., Ma, Z., Liu, B., Ren, L., Liu, A. K., & Chen, P. (2023). High-frequency observations of oceanic internal waves from geostationary orbit satellites. Ocean-Land-Atmosphere Research, 2, 0024. |
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| Kozlov, I. E., 2023 |
Kozlov, I. E., Kopyshov, I. O., Frey, D. I., Morozov, E. G., Medvedev, I. P., Shiryborova, A. I., ... & Stepanova, N. B. (2023). Multi-Sensor Observations Reveal Large-Amplitude Nonlinear Internal Waves in the Kara Gates, Arctic Ocean. Remote Sensing, 15(24), 5769. |
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| Baumann, T. M., & Fer, I., 2023 |
Baumann, T. M., & Fer, I. (2023). Trapped tidal currents generate freely propagating internal waves at the Arctic continental slope. Scientific Reports, 13(1), 14816. |
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| Purwandana, A., & Cuypers, Y., 2023 |
Purwandana, A., & Cuypers, Y. (2023). Characteristics of internal solitary waves in the Maluku Sea, Indonesia. Oceanologia, 65(2), 333-342. |
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