具有物理海洋、生物地球化学、流体力学、海洋工程与技术学术背景、工作经验与研究成果，长期从事海洋数值模拟，有一定出海与装备研发经验。研究方向主要为亚中尺度过程的生态效应、浮游-底栖耦合生态系统动力学、热带气旋生态效应。主要成果包括：基于高分辨率物理-生态耦合模式，揭示东海外陆架的亚中尺度垂向对流对初级生产力重要的支撑作用；基于浮游-底栖耦合生态系统动力学模式，研究了水体耗氧与沉积物耗氧在长江口外缺氧区年际变化中的作用，揭示了长江口北侧砂质区大范围缺氧的海、气、沉积物耦合机制；结合观测与模拟，研究了台风引起的海洋平流过程对长江口外缺氧区分布变化产生的影响。

在Environmental Science & Technology, Journal of Geophysical Research , Journal of Physical Oceanography , Frontiers in Marine Science , Ocean Engineering,  Renewable Energy，Journal of Ocean Engineering and Science等期刊发表论文30余篇。获国家发明专利4项。获Elsevier出版社旗下Journal of Ocean Engineering and Science编辑部主办的全球青年学者论文竞赛一等奖。承担国家重点研发计划、国家863计划、国家自然科学基金、自然资源部国家重大专项、自然资源部中德海洋与极地领域合作重大项目、英国劳氏教育基金、中央级公益性科研院所基本科研业务、卫星海洋环境动力学国家重点实验室自主课题、上海交通大学深蓝计划重点项目等科研任务。负责召集卫星海洋环境动力学国重室与自然资源部长三角海洋生态环境野外科学观测研究站联合发起的第一届海洋观测、模拟、应用协同创新青年学者论坛，在厦门大学主办的XMAS VI国际会议联合发起低氧主题分论坛。在Frontiers in Marine Science期刊联合发起专辑“Multi-scale Variability of Ecosystem Functioning in European and Chinese Shelf Seas”。在Frontiers in Marine Science期刊联合发起专辑“Multi-scale Variability of Ecosystem Functioning in European and Chinese Shelf Seas”。在Frontiers in Environmental Science期刊联合发起专辑“Key Observational Changes in Ocean Variability and the Effects of Climate Change”。

2024年入选自然资源部高层次科技创新人才工程“海洋生态系统动力学创新团队”。

代表性发表论文

1. 孟启承, 周锋*, 马晓, 倪晓波, 张文霞, 王斌, 李德望, 李明轩. 我国构建近海水体低氧的监测、评估、预测与应对链式体系[J]. 海洋学研究, 2024, 42(4): 138-140.

2. Meng Q*, Pan Y, Xuan J, Zhou F, Fan W, Di Y, Jiang Z-P, Xiao C, Zhang W, Daewel U, Chen J, Huang D and Chen Y, 2024. Leveraging Artificial Oxygenation Efficacy for Coastal Hypoxia by Taking Advantage of Local Hydrodynamics. Environmental Science & Technology, 58, 49, 21629–21640. doi: 10.1021/acs.est.4c07386.

3. YaMeng Ma, WenBin Yin, DaJi Huang, JiLiang Xuan, YuQing He, Qicheng Meng, Yi Wei, Feng Zhou, and JianFa Chen. Synoptic Cross-Shore Movements of Outer Salinity Fronts in China’s Changjiang River Plume. Journal of Physical Oceanography.doi:10.1175/JPO-D-23-0248.1

4. Chengqing Zhang, Qicheng Meng, Xiao Ma, Anqi Liu and Feng Zhou. Modeling Bottom Dissolved Oxygen on the East China Sea Shelf Using Interpretable Machine Learning. Journal of Marine Science and Engineering.doi:10.3390/jmse13020359

5. Qingyi Liu, Chunli Liu, Qicheng Meng, Bei Su, Haijun Ye, Bingzhang Chen, Wei Li, Xinyu Cao, Wenlong Nie, Nina Ma. Machine learning reveals biological activities as the dominant factor in controlling deoxygenation in the South Yellow Sea. Continental Shelf Research. doi:10.1016/j.csr.2024.105348

6. Ni X*, Zhou F*, Zeng D, Li D, Zhang T, Wang K, Ma Y, Meng Q, Ma X, Zhang Q, Huang D and Chen J, 2023. Long-Term Observations of Hypoxia off the Yangtze River Estuary: Toward Prediction and Operational Application. In Frontiers in Ocean Observing: Emerging Technologies for Understanding and Managing a Changing Ocean.E.S. Kappel, V. Cullen, M.J. Costello, L. Galgani, C. Gordó-Vilaseca, A. Govindarajan, S. Kouhi, C. Lavin, L. McCartin, J.D. Müller, B. Pirenne, T. Tanhua, Q. Zhao, and S. Zhao, eds, Oceanography 36(Supplement 1), doi: 10.5670/oceanog.2023.s1.13

7. Xu Y, Zhou F*, Meng Q, Zeng D, Yan T and Zhang W, 2023. How do topography and thermal front influence the water transport from the northern Laotieshan Channel to the Bohai Sea interior in summer?. Deep-Sea Research Part II, 208, 105261. doi: 10.1016/j.dsr2.2023.105261

8. Ye R, Zhou F*, Ma X, Zhou B, Zeng D, Liu C, Meng Q, Lin F, Xu M, Li H and Shou L, 2023. Energetic bottom current at the equatorial gap of the Ninety East Ridge in the Indian Ocean based on mooring data. Journal of Geophysical Research: Oceans, 128, e2022JC018974. doi: 10.1029/2022JC018974

9. Meng Q*, Zhang W, Zhou F*, Liao Y, Yu P, Tang Y, Ma X, Tian D, Ding R, Ni X, Zeng D and Schrum C, 2022. Water oxygen consumption rather than sediment oxygen consumption drives the variation of hypoxia on the East China Sea shelf. Journal of Geophysical Research: Biogeosciences, 127, e2021JG006705. doi: 10.1029/2021JG006705.

10. Meng Q, Zhou F*, Ma X, Xuan J, Zhang H, Wang S, Ni X, Zhang W, Wang B, Li D, Tian D, Li J, Zeng J, Chen J and Huang D, 2022. Response Process of Coastal Hypoxia to a Passing Typhoon in the East China Sea. Frontiers in Marine Science, 9:892797. doi: 10.3389/fmars.2022.892797.

11. Hu Z, Ma X*, Peng Y, Tian D, Meng Q, Zeng D, Liu Z, Zhou B, Li H, Zhou F*, 2022. A Large subsurface anticyclonic eddy in the eastern equatorial Indian Ocean. Journal of Geophysical Research: Oceans, 127, e2021JC018130. doi: 10.1029/2021JC018130

12. Zhu Y*, Feng Y, Browning TJ, Wen Z, Hughes DJ, Hao Q, Zhang R, Meng Q, Wells ML, Jiang Z, Dissanayake PAKN, Priyadarshani WNC, Shou L, Zeng J and Chai F, 2022. Exploring Variability of Trichodesmium Photophysiology Using Multi-Excitation Wavelength Fast Repetition Rate Fluorometry. Frontiers in Microbiology, 13:813573. doi: 10.3389/fmicb.2022.813573

13. Ma X, Liu A, Zhao Q, Wang B, Tian D, Meng Q, Zeng D, Li J, Huang D and Zhou F*, 2022. Temporal Variation of Summer Hypoxia off Changjiang Estuary During 1997–2014 and Its Association With ENSO. Frontiers in Marine Science, 9:897063. doi: 10.3389/fmars.2022.897063

14. Wang K*, Jin H, Meng Q, 2022. Nutritional potential of organic matter for benthic macrofauna in the surface sediments of the East China Sea from the perspective of essential amino acids. Aquaculture Research, 00: 1-9. doi: 10.1111/are.16113

15. Cui S, Wang Z*, Han J, Cui X and Meng Q, 2022. A deep learning method for solving high-order nonlinear soliton equations, Communications in Theoretical Physics, 74: 075007(13pp), doi: 10.1088/1572-9494/ac7202

16. Ding R, Xuan J*, Zhang T, Zhou L, Zhou F, Meng Q and Kang I-S*, 2021. Eddy-Induced Heat Transport in the South China Sea, Journal of Physical Oceanography, 51, 2329–2349, doi: 10.1175/JPO-D-20-0206.1.

17. Jin W, Liang C, Hu J, Meng Q, Lü H, Wang Y*, Lin F, Chen X and Liu X, 2020. Modulation Effect of Mesoscale Eddies on Sequential Typhoon-Induced Oceanic Responses in the South China Sea. Remote Sensing.  12(18):3059. doi: 10.3390/rs12183059

18. Meng Q, Xuan J*. Zhang W, Zhou F*, Hao Q, Zhao Q and Schrum C, 2020. Impact of Submesoscale Vertical Advection on Primary Productivity in the Southern East China Sea, Journal of Geophysical Research: Biogeosciences, 125, e2019JG005540. doi: 10.1029/2019JG005540.

19. Xiong P*, Dudzińska-Nowak J, Harff J*, Xie X, Zhang W, Chen H, Tao J, Chen H, Miluch J, Feldens P, Maciąg Ł, Osadczuk A, Meng Q and Zorita E, 2020. Modeling paleogeographic scenarios of the last glacial cycle as a base for source-to-sink studies: An example from the northwestern shelf of the South China Sea, Journal of Asian Earth Sciences, 203, 104542. doi: 10.1016/j.jseaes.2020.104542

20. Zhang W*, Xiong P, Meng Q, Dudzinska-Nowak J, Chen H, Zhang H, Zhou F, Harff J, 2020. Morphogenesis of a late Pleistocene delta off the south-western Hainan Island unraveled by numerical modeling, Journal of Asian Earth Sciences, 195, 104351. doi: 10.1016/j.jseaes.2020.104351

21. Zhou F*, Chai F, Huang D, Wells M, Ma X, Meng Q, Xue H, Xuan J, Wang P, Ni X, Zhao Q, Liu C, Su J and Li H, 2020. Coupling and Decoupling of High Biomass Phytoplankton Production and Hypoxia in a Highly Dynamic Coastal System: The Changjiang (Yangtze River) Estuary. Frontiers in Marine Science, 7:259, doi:10.3389/fmars.2020.00259.

22. Meng Q, Zhang C*, 2018. Analytical study on a submerged tubular wave energy converter. Renewable Energy, 118，955-964. doi: 10.1016/j.renene.2017.10.110

23. Meng Q*, Zhang C, 2016. A third-order KdV solution for internal solitary waves and its application in the numerical wave tank. Journal of Ocean Engineering and Science, 1(2), 93-108. doi: 10.1016/j.joes.2016.03.002

24. Xu G*, Meng Q, 2016. Waves induced by a two-dimensional foil advancing in shallow water. Engineering Analysis with Boundary Elements, 64, 150-157. doi: 10.1016/j.enganabound.2015.12.005

25. Zhou B, Wu G*, Meng Q, 2016. Interactions of fully nonlinear solitary wave with a freely floating vertical cylinder. Engineering Analysis with Boundary Elements, 69, 119-131.  doi: 10.1016/j.enganabound.2016.05.004

26. Zhang C*, Li Y, Meng Q, 2015. Fully nonlinear analysis of second-order sloshing resonance in a three-dimensional tank. Computers & Fluids, 116, 88-104. doi: 10.1016/j.compfluid.2015.04.016

27. Meng Q, Wang C, Chen Y*, Chen J, 2013. A simplified CFD model for air-lift artificial upwelling. Ocean Engineering, 72, 267-276. doi: 10.1016/j.oceaneng.2013.07.006

28. Wang C*, Meng Q, Huang H, Khoo B, 2013. Finite element analysis of nonlinear wave resonance by multiple cylinders in vertical motions. Computers & Fluids, 88, 557-568.  doi: 10.1016/j.compfluid.2013.10.012

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