Last update: 2025/06
代表著作:( * 表示通讯作者)
1. Wang, P.*, McWilliams, J. C., Yuan, J., & Liang, J.-H. (2025). Langmuir mixing schemes based on a modified K-profile parameterization. Journal of Advances in Modeling Earth Systems, 17, e2024MS004729.
2. Wang, P.*, McWilliams, J.C., Wang, D., & Yi, D.L. (2023). Conservative surface wave effects on a wind-driven coastal upwelling system. Journal of Physical Oceanography, 53(1), 37-55.
3. Wang, P.*, McWilliams, J.C., & Uchiyama, Y. (2021). A nearshore oceanic front induced by wave streaming. Journal of Physical Oceanography, 51(6), 1967-1984.
4. Wang, P.*, McWilliams, J.C., Uchiyama, Y., Chekroun, M.D., & Yi, D.L. (2020). Effects of wave streaming and wave variations on nearshore wave-driven circulation. Journal of Physical Oceanography, 50(10), 3025-3041.
5. Wang, P.*, & Özgökmen, T.M. (2018). Langmuir circulation with explicit surface waves from moving-mesh modelling. Geophysical Research Letters, 45(1), 216-226.
其他著作:
6. Yu, X., Yi, D. L., & Wang, P.* (2025). Reconstruction of Three-Dimensional Temperature and Salinity in the Equatorial Ocean with Deep-Learning. Remote Sensing, 17(12), 2005.
7. Wu, J., & Wang, P.* (2025). Langmuir Turbulence Effects on Coastal Surface Waves. Journal of Marine Science and Engineering, 13(6), 1067.
8. Yu, X., Yi, D. L., & Wang, P.* (2025). Enhancing Ocean Temperature and Salinity Reconstruction with Deep Learning: The Role of Surface Waves. Journal of Marine Science and Engineering, 13(5), 910.
9. Wu, J., & Wang, P.* (2025). Bottom Wave Streaming Intensifies a Nearshore Upwelling Front. Estuarine, Coastal and Shelf Science, 109410.
10. Wu, J., & Wang, P.* (2025). How do conservative surface wave effects influence a coastal upwelling front? Journal of Geophysical Research: Oceans, 130, e2024JC021404.
11. Yu, X., Yi, D. L., & Wang, P.* (2025). Predicting Surface Stokes Drift with Deep Learning. Water, 17(7), 983.
12. Peng, Z., & Wang, P.* (2025). Surface Wave Effects on Storm Surge: A Case Study of Typhoon Doksuri (2023). Journal of Marine Science and Engineering, 13(3), 478.
13. Yi, D.L., & Wang, P.* (2024). Global wavenumber spectra of sea surface salinity in the mesoscale range using satellite observations. Remote Sensing, 16(10), 1753.
14. Yi, D.L., Fan, K., He, S., & Wang, P. (2024). Sea-ice-loss slowdown modulates the sea surface salinification in the Kara-Laptev Seas since the 2008 summer. Environmental Research Letters, 19(8), 084022.
15. Li, Q., Reichl, B.G., Fox‐Kemper, B., Adcroft, A.J., Belcher, S.E., Danabasoglu, G., Grant, A.L., Griffies, S.M., Hallberg, R., Hara, T., Harcourt, R.R., Kukulka, T., Large, W.G., McWilliams, J.C., Pearson, B.C., Sullivan, P.P., van Roekel, L.P., Wang, P., & Zheng, Z. (2019). Comparing ocean surface boundary vertical mixing schemes including Langmuir turbulence. Journal of Advances in Modeling Earth Systems, 11, 3545– 3592.
16. Brett, G., Pratt, L., Rypina, I., & Wang, P. (2019). Competition between chaotic advection and diffusion: stirring and mixing in a 3-D eddy model. Nonlinear Process in Geophysics, 26(2), 37-60.
17. Zhai, L., Wang, X., Wang, P., Miralles‐Wilhelm, F., & Sternberg, L.D.S.L. (2019). Vegetation and location of water inflow affect evaporation in a subtropical wetland as indicated by the deuterium excess method. Ecohydrology, 12(4), e2082.
18. Wang, P.*, Özgökmen, T. M., & Haza, A. C. (2018). Material dispersion by oceanic internal waves. Environmental Fluid Mechanics, 18(1), 149-171.
19. Wang, P.*, & Özgökmen, T.M. (2016). Spiral inertial waves radiated from geophysical vortices. Ocean Modelling, 99, 22-42.
20. Wang, P.*, & Özgökmen, T.M. (2015). How do hydrodynamic instabilities affect 3D transport in geophysical vortices? Ocean Modelling, 87, 48-66.
21. Rypina, I., Pratt, L.J., Wang, P., Özgökmen, T.M., & Mezić, I. (2015). Resonance phenomena in a time-dependent, three-dimensional model of an idealized eddy. Chaos: An Interdisciplinary Journal of Nonlinear Science, 25(8), 087401.
22. Pratt, L.J., Rypina, I.I., Özgökmen, T.M., Wang, P., Childs, H., & Bebieva, Y. (2014). Chaotic advection in a steady, three-dimensional, Ekman-driven eddy. Journal of Fluid Mechanics, 738, 143.
23. Wang, P. (2016). Material dispersion by ocean eddies and waves. University of Miami. Ph.D. Dissertation.