朱贵勋，博士，主要从事船舶与海洋工程领域的基础与应用研究。2015年和2018年于大连理工大学船舶工程学院分别获得学士和硕士学位。2018年赴英国普利茅斯大学攻读博士研究生，导师为海洋可再生能源领域著名专家、皇家工程院院士Deborah Greaves教授，郑思明教授（现浙江大学）和Jason Hughes博士。并于2023年获得博士学位，同年开始在新加坡国立大学工程和环境学院从事博士后研究。作为主要骨干参与中国新加坡旗舰合作项目《Development and Demonstration of a Novel Floating Hybrid Tidal-Wave Energy System》，新加坡国家级海洋工程类项目《Enhancing Offshore System Productivity, Integrity and Survivability in Extreme Environments》，合作PI为B.C. Khoo教授和Yuzhu Li教授。2025年回到大连理工大学，担任助理教授。迄今已发表学术论文21篇，其中SCI收录17篇，以第一作者或通讯作者身份发表SCI论文11篇，包括Computer Methods in Applied Mechanics and Engineering、Journal of Computational Physics、Energy、Ocean Engineering等领域Top期刊。曾承担Physics of Fluids、JMSE等SCI期刊的审稿人，SCI期刊Mathematics的客座编辑。研究聚焦于海洋可再生能源装置，高精度高效无网格数值计算方法，流固耦合基础问题研究等方面。

主要研究方向：

（1）海洋可再生能源：致力于海洋可再生能源装置的水动力性能及其极限海况下的生还能力能力研究

（2）光滑粒子流体动力学（SPH）：发展独立自主的大规模高精度高效无网格数值方法

（3）流固耦合基础研究：非线性波浪与结构物作用机理研究，多相流入水问题研究

除此之外，还有山体滑坡入水和人工智能预测海洋平台运动的研究经历。

诚邀对海洋可再生能源、数值计算方法、流固耦合等方向感兴趣的本科生、硕士研究生及博士研究生加入，共同开展高水平科研工作。

代表性论文：

1.Zhu, G., Zheng, S., Ren. Y.., Li, Pearl L. (2025). Iterative high-order weakly compressible smoothed particle hydrodynamics model for viscous fluid flows. Computer methods in applied mechanics and engineering, 447,  118339. 

2.Zhu, G., Cui. Y., Khoo, B.C., Zheng, S., Yu, Z., Gao, Y. (2024). A parallel multi-resolution SPH model with local time stepping. Journal of Computational Physics, 508, 113039. 

3.Zhu, G., Samuel, J., Zheng, S., Greaves, D., Hughes, J., & David, S. (2023). Numerical investigation on the hydrodynamic performance of a 2D U-shaped Oscillating Water Column wave energy converter. Energy, 274, 127357. 

4.Zhu, G., Hughes, J., Zheng, S.*, & Greaves, D. (2023). A Novel MPI-based Parallel Smoothed Particle Hydrodynamics Framework with Dynamic Load Balancing for Free Surface Flow. Computer Physics Communications. 108608.

5.Zhu, G., Shahroozi, Z., Zheng, S., and Greaves, D. (2023). Experimental study of interactions between focused wave and a point absorber wave energy converter. Ocean Engineering, 287, 115815. 

6.Zhu, G., Hughes, J., Zheng, S., & Greaves, D. (2023). Development of a Two-dimensional Coupled Smoothed Particle Hydrodynamics Model and Its Application to Nonlinear Wave Simulations. Computer & Fluids, 266, 106024.

7.Zhu, G., Graham, D., Zheng, S. *, Hughes, J., & Greaves, D. (2020). Hydrodynamics of onshore oscillating water column devices: A numerical study using smoothed particle hydrodynamics. Ocean Engineering, 218, 108226.

8.Zhu, G., & Zou, L.* (2020). An integrated smoothed particle hydrodynamics model for complex interfacial flows with large density ratios. International Journal for Numerical Methods in Fluids, 92(8), 950-975.

9.Zhu, G., Zou, L., Chen, Z., Wang, A., & Liu, M.* (2018). An improved SPH model for multiphase flows with large density ratios. International Journal for Numerical Methods in Fluids, 86(2), 167-184.

10.Zheng, S., Zheng, H., Michele, S., Zhu, G.*, Lee, Y.C. and Greaves, D., (2025). Wave power extraction from a U-shaped oscillating water column consisting of a flexible bottom-standing front wall. Renewable Energy, 123173.

11.Zheng, S., Antonini, A., Zhang, Y., Miles, J., Greaves, D., Zhu, G.*, & Iglesias, G. (2020). Hydrodynamic performance of a multi-Oscillating Water Column (OWC) platform. Applied Ocean Research, 99, 102168.

12.Zheng, S.*, Zhu, G., Simmonds, D., Greaves, D., & Iglesias, G. (2020). Wave power extraction from a tubular structure integrated oscillating water column. Renewable Energy, 150, 342-355. 

13.Zheng, S.*, Meylan, M., Zhu, G., Greaves, D., & Iglesias, G. (2020). Hydroelastic interaction between water waves and an array of circular floating porous elastic plates. Journal of Fluid Mechanics, 900.

14.Hui, D., Wang, G., Huang, Y., Zhu, G., and Li, W., 2024. Numerical Simulation of a Marine Landslide in Gas Hydrate-Bearing Sediments Using L-GSM. Journal of Marine Science and Engineering, 12(12), 2274.

15.Zou, L.*, Zhu, G., Chen, Z., Pei, Y., & Zong, Z. (2018). Numerical investigation on the water entry of convex objects using a multiphase smoothed particle hydrodynamics model. International Journal of Computational Methods, 15(02), 1850008.