职称：Research Associate

邮箱：Qijie.Li@whu.edu.cn

个人网站：

https://www.researchgate.net/profile/Qijie-Li

研究领域：

研究领域：城市水利、水力学及河流动力学、流体力学

研究方向：城市水系统与水安全、城市水过程模拟与实验、城市水循环与洪涝致灾机理、城市地下空间防洪与安全、城市水资源与水环境、流域城市群洪水风险管理、城市韧性与智慧水利

教育背景：

2008.09-2012.06 华中科技大学，船舶与海洋工程专业，本科

2008.09-2012.06 华中科技大学，德语专业，本科

2012.09-2015.09 海军工程大学，动力工程及工程热物理专业，硕士

2015.10-2019.04 卡迪夫大学（Cardiff University，UK），Civil Engineering，博士

工作经历：

2021-2023 武汉大学，水利水电学院，博士后

2023-至今 剑桥大学（University of Cambridge，UK）, 副研究员

开设课程：

《港口规划与平面布置》（本科生）

《计算水动力学》（研究生）

代表性科研项目：

国家自然科学基金青年科学基金项目：城市典型地下空间洪涝致灾的水动力学机理及模拟技术（2023~2025，主持）

中国博士后科学基金特别资助项目：变化环境下城市暴雨洪涝致灾的水动力学机理研究（2023~至今，主持）

中央高校青年教师资助项目：城市地下空间洪水演进模拟与风险评估（2022~2023，主持）

中国博士后科学基金面上项目：城市典型地下空间洪涝致灾的水动力学机理及风险评估（2022~至今，主持）

西北旱区生态水利国家重点实验室开放研究基金项目：变化环境下城市洪涝致灾机理与减灾对策研究（2024~2025，主持）

国家自然科学基金重点国际（地区）合作与交流项目：植物驱动下的河岸带物理生境演变机制与修复理论研究（2024-2028，参与）

国家自然科学基金联合基金项目：黄河中下游水沙产输预报与水库智能调度关键技术（2023~2026，参与）

国家自然科学基金牛顿高级学者基金项目：城市洪涝过程的水动力学机理与数值模拟研究（2020~2022，参与）

国家自然科学基金重大项目课题：长江中下游典型城市水问题成因与调控机理（2023，参与）

国家杰出青年科学基金：河流动力学 (2018-2022，参与)

The Royal Society of UK, Newton Advanced Fellowship: Studies on hydrodynamic mechanisms of urban floods and numerical modelling（2020-2023，参与）

The European Regional Development Fund (ERDF)（2016~2019, 参与)

学术兼职：

Member (Young Professionals), International Association of Hydro-environmental Engineering and Research (IAHR), 2022

Member (Young Professionals), International Water Association (IWA), 2023

奖励与荣誉：

Best Presentation Award for “Gregynog Conference”, UK, 2018

The First Prize of the 10th National Graduate Mathematics Modeling Competition (Team leader), 2013

National Scholarships of China, HUST, 2011

华中科技大学“校三好学生”，2011

代表性学术成果：

期刊论文：

Li, Qijie, Xia Junqiang*, Zhou Meirong, Deng Shanshan, Dong Boliang. (2024) Risk assessment on metro tunnel evacuation in devastating urban flooding events, Tunnelling and Underground Space Technology, 144, 105540.

Li, Qijie, Xia, Junqiang*, Dong, B., Liu, Y., Wang, X. (2023): Risk assessment of individuals exposed to urban floods. International Journal of Disaster Risk Reduction, 88, 103599.

Li, Qijie, Xia, Junqiang*, Dong, B., Zhou, M. (2022): Near-field flow dynamics of grate inlets during urban floods. Physics of Fluids, 34(8), 87111. Featured Article

Li, Qijie, Xia, Junqiang*, Xie, Z., Zhou, M., Deng, S. (2022): Hazard and vulnerability in urban inundated underground space: hydrodynamic analysis of human instability for stairway evacuation. International Journal of Disaster Risk Reduction, 2022,70, 102754.

Li, Qijie, Xia, Junqiang*, Zhou, M., Deng, S., Zhang, H., Xie, Z. (2022): Physical Modelling of Energy Losses at Surcharged Three-way Junction Manholes in Drainage System. Water Science and Technology, 85(4): 1011-1026.

Li, Jun, Liu, Yongbao, Li, Qijie*, (2022): Intelligent fault diagnosis of rolling bearings under imbalanced data conditions using attention-based deep learning method. Measurement, 189, 110500.

Li, Jun, Liu, Yongbao, Li, Qijie*, (2022): Generative Adversarial Network and Transfer Learning Based Fault Detection for Rotating Machinery with Imbalance Data Condition. Measurement Science and Technology, 33, 045103.

Li, Qijie, Xia, Junqiang*, Yokoi, K.*, Omar, S. (2021): Boundary variation diminished conservative semi-Lagrangian method for both compressible and incompressible flows. Physics of Fluids, 33(11), 117114.

Li, Qijie*, Yokoi, Kensuke*, Xie, Z., Omar, S., Xue, J. (2021): A fifth-order high-resolution shock-capturing scheme based on modified weighted essentially non-oscillatory method and total boundary variation diminishing algorithm for compressible flows and compressible two-phase flows. Physics of Fluids, 33(5), 056104.

Li, Qijie, Omar, S., Deng, X., Yokoi, Kensuke*. (2017): Constrained Interpolation Profile Conservative Semi-Lagrangian Scheme Based on Third-Order Polynomial Functions and Essentially Non-Oscillatory (CIP-CSL3ENO) Scheme, Communications in Computational Physics, 22(3): 765-788.

Li, Qijie, Zhang, Z.*, Gu, J., Wang, C., Li, B., Gao, L. (2013): Steady Motions Performance of an Underwater Glider with Pump on the Vertical Plane. Applied Mechanics and Materials, 387, 310-313.