教育经历[1]1987.09‐1994.04大连理工大学港口及航道工程专业（学士和硕士）[2]1995.03‐1997.08大连理工大学近海工程专业（博士）工作经历[1]1994.04‐1995.03青岛市港务局[2]1997.07‐现在中国海洋大学工程学院讲师/副教授/教授/博导[3]1999.10‐2001.09日本京都大学博士后[4]2008.08‐2016.11中国海洋大学工程学院海洋工程系主任[5]2009.03‐2015.12山东省海洋工程重点实验室副主任[6]2011.03‐2011.08葡萄牙里斯本理工大学合作研究[7]2013.06‐2013.08葡萄牙里斯本大学合作研究[8]2014.07‐2014.10美国华盛顿大学高级研究学者

[1] 海洋动力环境的数值重构 [2] 海洋环境要素的随机分析 [3] 海洋环境与结构物的作用 [4] 灾害风险评估与工程防灾

[1] 国际船舶海洋结构大会（ISSC）委员 [2] 中国水利教育协会高等教育分会理事 [3] 《海洋工程》编辑委员会委员

[1] The application of Grey Markov model for forecasting annual maximum water level at hydrological station. Journal of Ocean University of China, 2012, 11(1): 13 - 17. [2] Numerical simulation of multi - directional random wave transformation in a yacht port. Journal of Ocean University of China, 2012, 11(3): 315 - 322. [3] Joint occurrence period of wind speed and wave height based on both service term and risk probability. Journal of Ocean University of China, 2012, 11(4): 488 - 494. [4] Bivariate maximum entropy distribution of significant wave height and peak period. Ocean Engineering, 2013, 59: 86 - 99. [5] Parameter estimation of the maximum entropy distribution of significant wave height. Journal of Coastal Research, 2013, 29(3): 597 - 604. [6] Estimating storm surge intensity with Poisson bivariate maximum entropy distributions based on Copulas. Natural Hazards, 2013, 68(2): 791 - 807. [7] Return value estimation of significant wave heights with maximum entropy distribution. Journal of Offshore Mechanics and Arctic Engineering, 2013, 135(3), 031103. [8] Interval estimations of return wave height based on maximum entropy distribution. Journal of Coastal Research, 2014, 30(5): 967 - 974. [9] Prediction of the mooring force of a 2 - D floating oil storage tank. Journal of Ocean University of China, 2014, 13(6): 901 - 910. [10] Bivariate distribution of group height and group length for ocean waves using the copula method. Coastal Engineering, 2015, 96: 49 - 61. [11] Trivariate maximum entropy model of significant wave height, wind speed and relative direction. Renewable Energy, 2015, 78: 538 - 549. [12] A Storm surge intensity classification based on extreme water level and concomitant wave height. Journal of Ocean University of China, 2015, 14(2): 237 - 244. [13] Long - term characteristics and extreme parameters of currents and sea levels in the Bohai Sea based on 20 - year hindcast data. Natural Hazards, 2015, 76(3): 1603 - 1624. [14] Study of vertical breakwater reliability based on copulas. Journal of Ocean University of China, 2016, 15(2): 232 - 240. [15] Assessments of wave energy in the Bohai Sea, China. Renewable Energy, 2016, 90: 145 - 156. [16] Estimation of design sea ice thickness with maximum entropy distribution by particle swarm optimization method. Journal of Ocean University of China, 2016, 15(3): 423 - 428. [17] Sea state conditions for marine structures’ analysis and model tests. Ocean Engineering, 2016, 119: 309 - 322. [18] Assessment of wind energy and wave energy resoures in Weifang sea area. International Journal of Hydrogen Energy, 2016, 41(35): 15805 - 15811. [19] A preliminary study on the intensity of cold wave storm surge of Laizhou Bay. Journal of Ocean University of China, 2016, 15(6): 987 - 995. [20] Nonlinear contact between pipeline’s outer wall and slip - on buckle arrestor’s inner wall during buckling process. Journal of Ocean University of China, 2017, 16(1): 42 - 48. [21] Joint return probability analysis of wind speed and rainfall intensity in typhoon - affected sea area. Natural Hazards, 2017, 86(3): 1193 - 1205. [22] Wave transformation over submerged breakwaters by the constrained interpolation profile method. Ocean Engineering, 2017, 120: 294 - 303. [23] Long - term statistics of extreme tsunami water height at Crescent City. Journal of Ocean University of China, 2017, 16(3): 437 - 446. [24] Met - Ocean design parameter estimation for fixed platform based on copula functions. Journal of Ocean University of China, 2017, 16(4): 635 - 648. [25] Study on temporal and spatial characteristics of cold waves in Shandong Province of China. Natural Hazards, 2017, 88(3): 191 - 219. [26] Joint probability design of marine environmental elements for wind turbines. International Journal of Hydrogen Energy, 2017, 42(29): 18595 - 18601. [27] Analysis of buoyancy module auxiliary installation technology based on numerical simulation. Journal of Ocean University of China, 2018, 17(2): 267 - 280. [28] Intensity division of the sea ice zones in China. Cold Regions Science and Technology, 2018, 151: 179 - 187. [29] Long - term wind and wave energy resource assessment in the South China Sea based on 30 - year hindcast data. Ocean Engineering, 2018, 136: 58 - 75. [30] Stochastic model to estimate extreme water level for port engineering design. Journal of Ocean University of China, 2018, 17(4): 744 - 752. [31] Modelling wave transmission and overtopping based on energy balance equation. Journal of Ocean University of China, 2018, 17(5): 1033 - 1043. [32] Wave energy assessment in the China adjacent Seas on the basis of a 20 - year SWAN simulation with unstructured grids. Renewable Energy, 2019, 136: 275 - 295. [33] Combined bearing capacity of spudcans on double layer deposit of strong - over - weak clays. Journal of Ocean University of China, 2019, 18(1): 133 - 143. [34] Spudcan penetration simulation using CEL method with thermo - mechanical coupled analysis. Journal of Ocean University of China, 2019, 18(2): 317 - 327. [35] Wave energy assessment based on trivariate distribution of significant wave height, mean period and direction. Applied Ocean Research, 2019, 87: 47 - 63. [36] Wind and wave energy resources assessment around the Yangtze River Delta. Ocean Engineering, 2019, 182: 75 - 89. [37] Approximate theoretical solution of the movement and erosion of solid particles in a 90° bend. Wear, 2019, 430 - 431: 233 - 244. [38] Long - term and inter - annual variations of tropical cyclones affecting Taiwan region. Regional Studies in Marine Science, 2019, 30: 100721. [39] Probability distribution of wave periods in combined sea states with finite mixture models. Applied Ocean Research, 2019, 92: 101938. [40] Investigation on deformation response of submarine pipeline subjected to impact loads by dropped objects. Ocean Engineering, 2019, 194: 106638. [41] Statistical prediction of annual sea - ice formation and duration at Qinhuangdao observation station. Journal of Ocean University of China, 2019, 18(6): 1265 - 1272. [42] Modelling long - term joint distribution of significant wave height and mean zero - crossing wave period using a copula mixture. Ocean Engineering, 2019, 197: 106856. [43] System reliability analysis of an offshore jacket platform. Journal of Ocean University of China, 2020, 19(1): 47 - 59. [44] Numerical study of the run - up of a solitary wave after propagation over a saw - tooth - shaped submerged breakwater. Int J Naval Arch & Ocean Eng, 2020, 12: 283 - 296. [45] Long - term variations of wind and wave conditions in the Taiwan Strait. Regional Studies in Marine Science, 2020, 36: 101256. [46] A novel model to predict significant wave height based on Long Short - Term Memory network. Ocean Engineering, 2020, 205: 107298. [47] Experimental and numerical study of submarine pipeline response to hooking loads. Ocean Engineering, 2020, 207: 107392. [48] Collision failure risk analysis of falling object on subsea pipelines based on machine learning scheme. Engineering Failure Analysis, 2020, 114: 104601. [49] Bivariate copula modelling of successive wave periods in combined sea states. Estuarine. Coastal and Shelf Science, 2020, 242: 106860. [50] Wind and wave climate characteristics and extreme parameters in the Bay of Bengal. Regional Studies in Marine Science, 2020, 39: 101403. [51] Joint distribution of individual wave heights and periods in mixed sea states using finite mixture models. Coastal Engineering, 2020, 161: 103773. [52] Estimating design loads with environmental contour approach using copulas for an offshore jacket platform. Journal of Ocean University of China, 2020, 19(5): 1029 - 1041. [53] Interaction of solitary wave with submerged breakwater by smoothed particle hydrodynamics. Ocean Engineering, 2020, 216: 108108. [54] A multi - load joint distribution model to estimate environmental design parameters for floating structures. Ocean Engineering, 2020, 217: 107818. [55] Joint distribution of significant wave height and zero - up - crossing wave period using mixture copula method. Ocean Engineering, 2021, 219: 108305. [56] Extended variable time step Adams - Bashforth - Moulton method for strongly coupled fluid - structure interaction simulation. Ocean Engineering, 2021, 219: 108335. [57] Generating shallow - and intermediate - water waves using a line - shaped mass source wavemaker. Ocean Engineering, 2021, 220: 108493. [58] Probabilistic fatigue surrogate model of bimodal tension process for a semi - submersible platform. Ocean Engineering, 2021, 220: 108501. [59] Predicting the overall horizontal bearing capacity of jack - up rigs using deck - foundation - soil coupled model. Journal of Engineering for the Maritime Environment, 2021, 235(1): 213 - 224. [60] Reliability analysis of mooring lines for floating structures using ANN - BN inference. Journal of Engineering for the Maritime Environment, 2021, 235(1): 236 - 254. [61] Co - occurrence probability of typhoon surges affecting multiple estuaries in the northern coastal region of Taiwan. Regional Studies in Marine Science, 2021, 42: 101582. [62] Mooring tension prediction based on BP neural network for semi - submersible platform. Ocean Engineering, 2021, 223: 108714. [63] Statistical description of wave groups in three types of sea states. Ocean Engineering, 2021, 225: 108745. [64] Estimation of characteristic extreme response for mooring system in a complex ocean environment. Ocean Engineering, 2021, 225: 108809. [65] Long - term extreme response analysis for semi - submersible platform mooring systems. Journal of Engineering for the Maritime Environment, 2021, 235(2): 463 - 479. [66] Study on spudcan reinstallation next to a footprint using large deformation finite element method. Journal of Engineering for the Maritime Environment, 2021, 235(2): 532 - 545. [67] Risk - based integrity model for offshore pipelines subjected to impact loads from falling objects. Journal of Engineering for the Maritime Environment, 2021, 235(2): 623 - 641. [68] Analysis of solid particle erosion in direct impact tests using the discrete element method. Powder Technology, 2021, 383: 256 - 269. [69] An integrated reliability analysis model of sheet pile wharfs based on virtual support beam model and artificial intelligence algorithm. KSCE Journal of Civil Engineering, 2021, 25(7): 2613 - 2630. [70] Statistical properties of group height and group length in combined sea states. Coastal Engineering, 2021, 166: 103897.