个人简历

教育背景\r
1984年毕业于清华大学水利工程系\r
1986年获清华大学水力学与河流动力学专业硕士学位\r
1990年获日本东京大学海岸工程专业博士学位\r
\r
工作履历\r
2001年至今 清华大学水利水电工程系教授\r
2001年10月 教育部长江学者奖励计划特聘教授\r
2003年-2008年任水利系系主任\r
1999年-2000年 上海交通大学工程力学系教授\r
1997年-1999年 日本东京大学土木工程系副教授\r
1993年-1997年 日本长崎大学土木工程系副教授

研究领域

"水波理论及海岸水动力学\r
水沙两相流理论及海岸泥沙动力学\r
海气相互作用及台风风暴潮过程\r
海岸工程建筑物先进设计理论\r
海岸环境的安全性及舒适性评价与沿岸地区可持续发展战略"

近期论文

Shan K., Yu X.* (2020). A Simple Trajectory Model for Climatological Study of Tropical Cyclones. Journal of Climate, 33 (18): 7777–7786.\r
\r
Shan K., Yu X.* (2020). Enhanced understanding to poleward migration of tropical cyclone genesis. Environmental Research Letters, 15: 104062\r
\r
Shan K., Yu X.* (2020). Interdecadal variability of tropical cyclone genesis frequency in western North Pacific and South Pacific ocean basins. Environmental Research Letters, 15: 064030.\r
\r
Xu Y., Yu X.* (2020). Enhanced formulation of wind energy input into waves in developing sea. Progress in Oceanography, 186: 102376.\r
\r
Lin X.*, Chamecki M., Yu X. (2020). Aerodynamic and deposition effects of street trees on PM2.5 concentration: from street to neighborhood scale. Building and Environment, 185: 107291. \r
\r
Shi H., Si P., Yu X.* (2019). A two-phase SPH model for massive sediment motion in free surface flows. Advances in Water Resources, 129: 80-98.\r
\r
Si P., Shi H., Yu X.* (2019). A general frictional-collisional model for dense granular flows. Landslides, 16: 485-496.\r
\r
Si P., Shi H., Yu X.* (2018). A general numerical model for surface waves generated by granular material intruding into a water body. Coastal Engineering, 142: 42-51.\r
\r
Si P., Shi H., Yu X.* (2018). Development of a mathematical model for submarine granular flows. Physics of Fluids, 30: 083302.\r
\r
Liang L., Yu X.*, Bombardelli F. (2018). A general formulation of relative motion between two phases in sediment-laden water flows. International Journal of Multiphase Flow, 109: 63-83. \r
\r
Chen Y., Zhang F.*, Green B. W., Yu X.* (2018). Impacts of ocean cooling and reduced wind drag on Hurricane Katrina (2005) based on numerical simulations. Monthly Weather Review, 146: 287-306. \r
\r
Wen H., Ren B.*, Zhang X., Yu X. (2018). SPH modeling of wave transformation over a coral reef with seawall. Journal of Waterway, Port, Coastal and Ocean Engineering, 145(1): 04018026\r
\r
Wen H., Ren B.*, Yu X. (2018). An improved SPH model for turbulent hydrodynamics of a 2D oscillating water chamber. Ocean Engineering, 150: 152-166.\r
\r
Lin X., Chamecki M.*, Katul G. G., Yu X. (2018). Effects of leaf area index and density on ultrafine particle deposition onto forest canopies: A LES study. Atmospheric Environment, 189: 153-163. \r
\r
Si P., Aaron J., McDougall S., Lu J., Yu X.*, Roberts N., Clague J. J. (2018). A non-hydrostatic model for the numerical study of landslide-generated waves. Landslides, 15:711–726. \r
\r
Shi H., Yu X.*, Dalrymple R. A. (2017). Development of a two-phase SPH model for sediment laden flows. Computer Physics Communications, 221: 259-272.\r
\r
Liang L., Yu X.*, Bombardelli F. (2017). A general mixture model for sediment laden flows. Advances in Water Resources, 107: 108–125. \r
\r
Chen Y., Yu X.* (2017). Sensitivity of storm wave modeling to wind stress evaluation methods. Journal of Advances in Modelling Earth System, 9: 893–907. \r
\r
Chen Y., Yu X.* (2016). Enhancement of wind stress evaluation method under storm conditions. Climate Dynamics, 47: 3833-3843.\r
\r
Liu Y., Yu X.* (2016). A coupled phase-field and volume-of-fluid method for accurate representation of limiting water wave deformation. Journal of Computational Physics, 321: 459-475. \r
\r
Liang T., Yu X.* (2016). A numerical study of sea-spray aerosol motion in a coastal thermal internal boundary layer. Boundary-Layer Meteorology, 160: 347-361. \r
\r
Liang T., Chamecki M., Yu X. (2016). Sea salt aerosol deposition in the coastal zone: A large eddy simulation study. Atmospheric Research, 180: 119-127. \r
\r
Yu X.*, Niu X., Zhou H. (2015). Statistical law for tropical cyclone motion in the Northwest Pacific Ocean. International Journal of Climatology, 36: 1700-1707. \r
\r
Lin X., Yu X.* (2015). A finite difference method for effective treatment of mild-slope wave equation subject to non-reflecting boundary conditions. Applied Ocean Research, 53: 179-189. \r
\r
Chen X., Yu X.* (2015). A numerical study on oscillatory flow-induced sediment motion over vortex ripples. Journal of Physical Oceanography, 45:228-246. \r
\r
Shi H., Yu, X.* (2015). An effective Euler-Lagrange model for suspended sediment transport by open channel flows. International Journal of Sediment Research, 30: 361-370. \r
\r
Niu X., Yu X. (2014). Numerical study on wave propagation over a fluid-mud layer with different bottom conditions, Ocean Dynamics, 64(2):293-300. \r
\r
Chen X., Niu X., Yu X.* (2013). Near-bed sediment condition in oscillatory sheet flows. Journal of Waterway, Port, Coastal, and Ocean Engineering (ASCE), 139(5):393-403. \r
\r
Shi H., Yu X.* (2013). Application of transport timescales to coastal environmental assessment: A case study. Journal of Environmental Management, 130:176-184.\r
\r
Niu X., Yu X.* (2012). An analytic solution for combined wave diffraction and refraction around a vertical cylinder with idealized scour pit. Coastal Engineering, 67:80-87.