姓名:张红
职称:副教授/硕导
所在系(所、中心):海洋工程系港航教研室
通讯地址:山东省青岛市黄岛区古镇口三沙路1299号中国海洋大学西海岸校区工程学院A419
电子信箱:zhanghong9645@ouc.edu.cn
教育经历:
[1] 2017.09-2022.01,中国海洋大学,环境地质工程专业,博士
[2] 2014.09-2017.06,中国海洋大学,环境地质工程专业,硕士
[3]2010.09-2014.06,中国矿业大学,地质工程(岩土)专业,学士
工作经历:
[1] 2025.01-至今,中国海洋大学,工程学院,副教授
[2] 2022.03-2024.12,中国海洋大学,工程学院,讲师
[3] 2022.04-至今,中国海洋大学,工程学院,博士后
研究方向:
围绕海洋工程地质环境与灾害开展研究,具体包括
[1] 液化型海底滑坡启动机理与致灾机制
[2] 海洋动力-植被-海岸-构筑物互馈耦合机理
[3] 极端风暴作用下海洋风电场海床液化、冲刷灾害机理及防护
[4] 海底沉积物物理力学性质及原位监测技术
如果你对我的研究方向感兴趣,且勤奋,乐观,上进,欢迎报考我的研究生,我们携手共进!
讲授课程:
本科生:工程地质、工程地质实践、土力学、土力学实验、前沿技术实践
研究生:科技论文写作
部分科研项目:
[1]国家自然科学基金委员会,面上项目,基于水土多参量融合的风暴诱发海底滑坡机制与预警模型,2026.01-2029.12,主持
[2]国家自然科学基金委员会,青年基金,液化程度对黄河水下三角洲海底滑坡启动过程控制机理研究,2023.01-2025.12,主持
[3]中国电建集团华东院,技术开发应用项目,基于沉积物动力响应的风电基础稳定性评价模型研发,2022.11-2024.8,主持
[4]科技部,国家重点研发计划专题子课题,海洋动力灾害-海岸-植被-构筑物互馈机理与模拟技术,2023.11-2026.10,主持
[5]科技部,国家重点研发计划子课题,海底稳定性动态监测技术及滑坡预测方法,2024.11-2029.11,主持
[6]山东省博士后创新项目,黄河水下三角洲液化型滑坡滑动带特征及演化规律研究,主持
[7]青岛市博士后应用研究项目,液化型海底滑坡滑动带物理力学特征研究,主持
[8]山东省重点研发计划,气候变化背景下山东沿海动力灾害长期演变预测及环境信息服务保障平台研发,参与
[9]国家自然科学基金委员会,面上项目,基于现场原位观测的黄河水下三角洲海底滑坡启动过程与控制因素研究,2019.01-2022.12, 参与
[10]国家自然科学基金委员会,青年基金, 波致渗流对粉质土海床侵蚀影响的定量评价方法研究,2019.01- 2021.1, 参与
学术兼职:
国际地质灾害与减灾协会(ICGdR)海洋地质灾害与地质环境委员会(TC-4) 秘书长
国际工程地质与环境协会(IAEG) 海洋工程地质委员会(C34) 会员
中国岩石力学与工程学会海洋工程地质灾害防控分会会员
Journal of Marine Environmental Engineering 青年编委
Intelligent Geo-science青年编委
Engineering Geology、Ocean Engineering、Geomorphology等期刊审稿人
山东省民盟海洋委委员
科研奖励:
[1]2026年,浙江省岩土力学与工程科学技术(奖科技进步奖)特等奖
[2]2025年,日内瓦发明展金奖
[3]2024年,海洋工程科学技术奖一等奖
[4]2024年,《Geoenvironmental Disasters》最佳论文奖
[5]2023年,国际地质灾害与减灾协会优秀博士论文
[6]2023年,第二届全国博士后创新创业大赛海外(境外)赛,银奖
[7]2023年,全国创新创业优秀博士后
[8]2023年,国际地质灾害与防灾协会技术发明奖
[9]2023年,中国地质学会2022年度十大地质科技进展
[10]2022年,青岛市技术发明一等奖
[11]2022年,海洋工程科学技术奖二等奖
[12]2020年,山东省高等学校科学技术奖一等奖
[13]2022年,《海洋地质前沿》创刊40周年优秀作者
[14]2019年,ZHOUDI Award for Outstanding Presentation
[15]2018年,海洋工程科学技术奖一等奖
代表性学术论文:
在Engineering Geology、Journal of Geophysical Research:Oceans、Coastal Engineering、Ocean Engineering等领域权威期刊发表论文30余篇
[1]刘晓磊,程光伟,孟祥帅,刘浩,张红*,2026. 海底流滑灾害研究进展. 地质科技通报, 45(3), 1-18.
[2]Xiangshuai Meng, Xiaolei Liu, Hong Zhang, Xingsen Guo, Yide Wang, Dong-Sheng Jeng, 2026. A physics-informed neural network framework for wave-induced dynamic response in a poroelastic seabed. Computers and Geotechnics, 198, 108250.
[3]Bingchen Liang, Xuedong Wu, Hong Zhang*, Zhipeng Qu, Bo Yang, Guoxiang Wu, 2026. Modeling wave attenuation in salt marshes under variable vegetation and wave conditions using XBeach model with a new parameterization scheme. Ocean Engineering, 343, 123595.
[4]Haiyang Cheng, Bingchen Liang,Hong Zhang*,Dong Wang, Xiaolei Liu, 2025. Coupled numerical simulation of seabed response to focused wave loads around monopile foundation. Ocean Engineering, 341, 122453.
[5]Bingchen Liang, Haiyang Cheng,Hong Zhang*, Chenglin Zhou, Xingsen Guo, Bo Yang, Pengrui Zhu, Xiaolei Liu, 2025. Experimental Investigation on Pore Water Pressure Response Around Pile Foundations Under Wave and Cyclic Loads: Oscillatory Behavior and Amplitude Distribution. Ocean Engineering, 339, 122170.
[6]Simin Xu,Xiaolei Liu,Cheng Zhang,Hong Zhang,Botao Xie,Xingsen Guo, 2025.Numerical study on the stability of offshore pile-soil systems considering pore pressure response induced by extreme storms. Ocean Engineering, 329, 121178.
[7]Xiangshuai Meng, Xiaolei Liu, Yueying Wang, Hong Zhang, Xingsen Guo, 2024. Submarine landslide susceptibility assessment integrating frequency ratio with supervised machine learning approach. Applied Ocean Research, 153, 104237
[8]Xiaolei Liu, Xingyu Li, Hong Zhang, Yueying Wang, Qiang Zhang, Haoqiang Wei, Xingsen Guo, 2024. An experimental investigation of the effect of interfacial waves on the evolution of sliding zones in a liquefied seabed. Journal of Marine Science and Engineering, 12, 1355.
[9]Xingsen Guo, Xiangshuai Meng, Fei Han, Hong Zhang, Xiaolei Liu, 2024. Assessing the strength of deep-sea surface ultrasoft sediments with T-bar penetration: A machine learning approach. Engineering Geology, 338,107632.
[10]Xingsen Guo, Xiaolei Liu, Tianyuan Zheng, Hong Zhang, Yang Lu, Tiantao Li, 2024. A mass transfer-based LES modelling methodology for analyzing the movement of submarine sediment flows with extensive shear behavior. Coastal Engineering, 191, 104531.
[11]Zhigang Shan, Miaojun Sun, Wei Wang, Jing Zou, Xiaolei Liu, Hong Zhang, Zhijin Qiu, Bo Wang, Jinyue Wang, Shuai Yang, 2024. Investigating the role of wave process in the evaporation duct simulation by using an Ocean–Atmosphere–Wave coupled model. Atmosphere, 15(6), 707.
[12]Miaojun Sun, Zhigang Shan,Wei Wang, Simin Xu, Xiaolei Liu, Hong Zhang, Xingsen Guo, 2024. Numerical investigation into the stability of offshore wind power piles subjected to lateral loads in extreme environments. Journal of Marine Science and Engineering,12(6), 915.
[13]Yueying Wang, Xingsen Guo, Jinkun Liu, Fang Hou, Hong Zhang, Han Gao, Xiaolei Liu, 2024. A Methodology for Susceptibility Assessment of Wave-Induced Seabed Liquefaction in Silt-Dominated Nearshore Environments. Journal of Marine Science and Engineering, 12(5), 785
[14]Zhihan Fan, Xianming Zhu, Haibo Xu, Zhiwen Sun, Hong Zhang, Xianbin Bi, Cong Hu, Dequan Lu, Zhongqiang Sun, Kai Li, Yongzheng Quan, Yonggang Jia, 2023. A new method for long-term in situ monitoring of seabed interface evolution: A self-potential probe. Ocean Engineering, 280:114917.
[15]Xingsen Guo, Xiaolei Liu, Hong Zhang, Zhigang Shan, Miaojun Sun, 2023. Improved predictive model for the strength of fluidized seabed sediments with rate effect characteristics by full-scale spherical penetrometer tests. Computers and Geotechnics, 161:105535.
[16]Hong Zhang, Yang Lu, Xiaolei Liu, Xingyu Li, Zhenhao Wang, Chunsheng Ji, Chao Zhang, Zekun Wang, Shaodong Jing, Yonggang Jia, 2023. Morphology and origin of liquefaction-related sediment failures on the Yellow River Subaqueous Delta. Marine Petroleum and Geology, 153:106262.
[17]Xiaolei Liu, Yueying Wang, Hong Zhang, Xingsen Guo, 2023.Susceptibility of typical marine geological disasters: an overview. Geoenvironmental Disasters, 10:10.
[18]Xiaolei Liu, Yang Lu, Heyu Yu, Lukuan Ma, Xingyu Li, Weijia Li, Hong Zhang, Changwei Bian, 2022. In-Situ observation of storm-induced wave-supported fluid mud occurrence in the Subaqueous Yellow River Delta. Journal of Geophysical Research-Oceans,127(7): e2021JC018190.
[19]Xingsen Guo, Xiaolei Liu, Hong Zhang, Minqiang Li, Qianyu Luo, 2022. Evaluation of instantaneous impact forces on fixed pipelines from submarine slumps. Landslides,19:2889-2903.
[20]孙璐,单红仙,张红,刘汉露,贾永刚. 基于~(210)Pb、~(137)Cs分布和粒度特征的海床液化深度判定研究——以埕岛海域为例. 海洋学报,45(10):105-113.
[21]杜奇智,张红,程升,单红仙,2023. 基于数字图像测量系统的南海砂土剪切变形特性研究. 海洋湖沼通报,45(6):27-33.
[22]Hong Zhang, Xiaolei Liu, Anduo Chen, Weijia Li, Yang Lu, Xingsen Guo, 2021.Design and application of in situ test device of rheological characteristics measurement for liquefied submarine sediments. Journal of Marine Science and Engineering, 639 (9):9060639.
[23]Hong Zhang, Xiaolei Liu, Yonggang Jia, Qizhi Du, Yongfu Sun, Ping Yin, Hongxian Shan, 2020. Rapid consolidation characteristics of Yellow River-derived sediment: Geotechnical characterization and its implications for the deltaic geomorphic evolution. Engineering Geology, 270: 105578.
[24]Xiaolei Liu, Hong Zhang, Jiewen Zheng, Lei Guo, Yonggang Jia, Changwei Bian, Minqiang Li, Lukuan Ma, Shuyu Zhang, 2020. Critical role of wave-seabed interactions in the extensive erosion of Yellow River estuarine sediments. Marine Geology,426: 106208.
[25]刘晓磊,陈安铎,张红,陆杨,马路宽,贾永刚,2021. 黄河水下三角洲高浓度粘性泥沙流变特性及其影响因素. 海洋学报,43(5):127-134.
[26]刘晓磊,马路宽,张红,陆杨,陈安铎,张淑玉,2021. 应用声、光学仪器原位观测海底浮泥层动态变化的对比研究. 中国海洋大学学报,51(1): 86-93.
[27]Xiaolei Liu, Xiaoquan Zheng, Zhuangcai Tian, Hong Zhang, Tian Chen, 2020. Pressure Sensing Technique for Observing Seabed Deformation Caused by Submarine Sand Wave Migration. Journal of Marine Science and Engineering, 8(5):315.
[28]Yang Lu, Zhigang Duan, Jiewen Zheng, Hong Zhang, Xiaolei Liu, Shaoyang Luo, 2020. Offshore Cone Penetration Test and Its Application in Full Water-Depth Geological Surveys. IOPConf. Series: Earth and Environmental Science, 570, 42008.
[29]Xiaolei Liu, Shuyu Zhang, Jiewen Zheng, Hong Zhang, Yongang Jia, 2019. Experimental dynamic sediment behavior under storm waves with a 50 year recurrence interval in the Yellow River Delta. Anthropocene Coasts, 2: 229-243.
[30]张红,贾永刚,刘晓磊,魏志明,季春生,焦欣然,朱超祁,2019. 全海深海底沉积物力学特性原位测试技术. 海洋地质前沿,35(02): 4-12.
[31]张红,贾永刚,刘晓磊,张博文,申志聪,张夏滔,单红仙,2018. 黄土迁移入海后动力特性的试验研究.湖南大学学报, 45: 98-104.
[32]Xiaolei Liu, Jiewen Zheng, Hong Zhang, Shaotong Zhang, Baohua Liu, Hongxian Shan, Yonggang Jia, 2018. Sediment critical shear stress and geotechnical properties along the modern Yellow River Delta, China. Marine Georesources & Geotechnology, 36(8):875-882.
[33]Chaoqi Zhu, Xiaolei Liu, Hongxian Shan, Hong Zhang, Zhicong Shen, Bowen Zhang, Yonggang Jia, 2018. Properties of suspended sediment concentrations in the Yellow River Delta based on observation. Marine Georesources & Geotechnology, 36(1): 139-149.
[34]Xiaolei Liu, Maosheng Zhang, Hong Zhang, Yonggang Jia, Chaoqi Zhu, Hongxian Shan, 2016. Physical and mechanical properties of loess discharged from the Yellow River into the Bohai Sea, China. Engineering Geology, 227: 4-11.
[35]张红,贾永刚,刘晓磊,张少同,朱超祁,单红仙,2016. 黄土迁移入海过程中工程性质的变化研究.工程地质学报,24(5): 941-950.
授权发明专利:
共授权国内外发明专利28项,其中美国、欧盟、日本国际发明专利6项
[1] System for measuring mechanical properties of sea floor sediments at full ocean depths, Patent number: US16632509(美国专利)
[2] Second-generation in-situ test device for strength of shallow water sediment,Patent number: US16777757(美国专利)
[3] Seabed sediment mechanical properties measurementsystem suitable for use at full sea depth, Patent number: EP3855155(欧盟专利)
[4]フルデプスに適した海底堆積物の力学的性質測定 システム. Patent number: 2021-522500(日本专利)
[5] System for measuring mechanical properties of sea floor sediments at full ocean depths, Patent number: 2019-080722(欧盟专利)
[6]内部波発達エリアに使用される海底サンドウェーブの長期観測装置及び観測方法. Patent number: 2021-6941907(日本专利)
[7] 动态无损柱状取样的海底块体滑坡监测装置及其工作方法.发明专利,专利号:ZL 202310640254.9.
[8]一种针对长周期波浪的组合式消浪结构及装配式施工方法. 发明专利,专利号:ZL2025119123800
[9]基于电学探针组网监测系统的海底界面层三维可视化方法. 发明专利,专利号:ZL2026100696665
[10] 一种基于 BP 神经网络算法的海底斜坡失效概率评估分析方法. 发明专利,专利号:ZL2025119246514
[11] 一种设置桩基透空式防波堤的潮流水动力数值模拟方法. 发明专利,专利号:ZL202510502321.X
[12]一种柔性植被消浪的参数化计算方法,发明专利,专利号:ZL202411620845.0
[13]一种极端风浪流、滑坡荷载下风电桩基稳定性分析方法 ,发明专利,专利号:ZL202410680469.8
[14]一种探究波致沉积物再悬浮机制的水槽试验系统及方法 ,发明专利,专利号:ZL202411248777.X
[15]一种设置防波堤海域的波浪水动力数值模拟方法 ,发明专利,专利号:ZL202510120969.0
[16]海洋环境强扩散性沉积物羽流三维结构动态监测装置 ,发明专利,专利号:ZL202410727457.6
[17]一种极端环境下波致海床液化易发性的评价方法,发明专利,专利号:ZL202410546649.7
[18]深海原位十字板剪切试验装置及沉积物不同剪切面强度解析方法 ,发明专利,专利号:202210255338.6
[19]一种适用于全海深的无缆式海底观测平台. 发明专利,专利号:ZL201811246921.0.
[20]一种适用于全海深的海底沉积物力学特性原位测量装置. 发明专利,专利号:ZL201811244538.1.
[21]] 第二代滩浅海沉积物强度原位检测装置. 发明专利,专利号:ZL 201910166966.5.
[22]一种滩浅海沉积物强度原位测试系统. 发明专利,专利号:ZL 201910166857.3
[23] 一种适用于全海深的海底沉积物力学特性测量系统. 发明专利,专利号:ZL201811246959.8
[24] 适用于全海深的无缆式海底观测系统. 发明专利,专利号:ZL201811246923.X
[25] 一种海底滑坡监测的装置.发明专利. 授权专利号:ZL106768070B
[26]一种用于防止柱状取样器倾倒的侧推装置及使用方法. 发明专利,授权专利号:ZL202010070216.0
