周曾,教授,博士生导师
目前担任河海大学海岸带资源与环境研究所所长,兼任江苏省海岸海洋资源开发与环境安全重点实验室常务副主任、江苏省海洋湖沼学会理事、副秘书长等职务。主要从事河口海岸动力地貌学和海岸带保护修复等方面的教学与科研工作。先后在荷兰三角洲研究院、新西兰奥克兰大学、英国剑桥大学开展了访问研究。担任《Anthropocene Coasts》、《Frontiers in Marine Science》、《Earth Surface Processes and Landforms》等期刊的副主编或编委。主持包括国家自然基金、江苏省自然基金与各类行业专项、课题及应用项目等近20项,成果发表在包括《Earth-Science Reviews》《Geophysical Research Letters》《Water Resources Research》《海洋学报》等权威期刊,授权专利近10项,获教育部科技进步奖1项。工作以来,先后获得南京市留学人员科技活动项目择优资助项目(2017)、江苏省优秀青年基金(2020)、江苏省青蓝工程中青年学术带头人(2021)、国家级青年人才计划等人才项目(2021)。
教育背景
2012.03-2015.03 西班牙Cantabria大学 博士
专业:海岸科学与技术
2009.08-2011.07 荷兰Delft理工大学 硕士
英国Southampton大学
挪威科技大学(NTNU)
专业:海岸海洋工程与管理(欧盟Erasmus-Mundus奖学金项目)
2008.09-2009.07 河海大学,港口、海岸及近海工程专业 硕士研究生
2004.09-2008.06 河海大学,港口航道与近海工程专业 本科
工作及科研经历
2022.06-至今 河海大学 港口海岸与近海工程学院 教授
2019.06-2022.06 河海大学 港口海岸与近海工程学院 青年教授
2019.04-至今 河海大学 港口海岸与近海工程学院 海岸带资源与环境研究所所长
2016.01-2019.06 河海大学 港口海岸与近海工程学院 副教授
2018.06-2018.09 英国剑桥大学 地理学院 访问学者
2015.12-2016.12 新西兰Auckland大学 环境学院 荣誉学者
2015.07-2015.12 新西兰Auckland大学 助理研究员
2015.03-2015.06 荷兰Deltares三角洲水利研究院 研究职员
2013.09-2013.12 荷兰Deltares三角洲水利研究院 访问学者
2011.01-2011.07 英国HR Wallingford水利研究所 访学硕士生
研究方向
Ÿ 河口海岸水动力、泥沙运动以及地貌特征
Ÿ 潮滩生态动力过程、碳循环以及地貌演变
Ÿ 港口、海岸工程
教学
Ÿ 本科生课程:主持《海岸地貌学》,2学分
Ÿ 硕士生课程:主持《海岸地貌演变理论与应用》,2学分;参与《海岸修复理论与技术》,2学分
Ÿ 博士生课程:主持江苏高校省级外国留学生精品课程《Advanced Coastal Dynamics》, 2学分
代表性学术论文
[1] Zhou, Z., Wu, Y., Fan, D., Wu, G., Luo, F., Yao, P., Gong, Z. and Coco, G., 2022. Sediment sorting and bedding dynamics of tidal flat wetlands: Modeling the signature of storms. Journal of Hydrology, 610: 127913, doi:10.1016/j.jhydrol.2022.127913.
[2] Zhou, Z., Liang, M.-j., Chen, L., Xu, M.-p., Chen, X., Geng, L., Li, H., Serrano, D., Zhang, H.-y., Gong, Z. and Zhang, C.-k., 2022. Processes, feedbacks, and morphodynamic evolution of tidal flat–marsh systems: Progress and challenges. Water Science and Engineering, 15(2): 89-102, doi:10.1016/j.wse.2021.07.002.
[3] Zhang, H., Sun, T., Zhou, Z.*, Cao, H., Qiu, J. and Huang, X., 2022. Increased river flow enhances the resilience of spatially patterned mudflats to erosion. Water Research, 220, doi:10.1016/j.watres.2022.118660.
[4] 周曾, 陈璐莹, 蒋春海, 储鏖, IanTownend and 张长宽, 2022. 河口地貌对潮汐不对称性影响的数值模拟研究. 海洋学报, 44(7): 72-81, doi:10.12284/hyxb2022120.
[5] Xie, D., Schwarz, C., Kleinhans, M.G., Zhou, Z. and van Maanen, B., 2022. Implications of Coastal Conditions and Sea-Level Rise on Mangrove Vulnerability: A Bio-Morphodynamic Modeling Study. Journal of Geophysical Research: Earth Surface, 127(3): e2021JF006301, doi: 10.1029/2021JF006301.
[6] Hu, Z., Zhou, Z., Chen, Y., Mudd, S.M., Möller, I. and Gong, Z., 2022. Editorial: Coastal biogeomorphology. Frontiers in Marine Science, 9, doi:10.3389/fmars.2022.988804.
[7] Wei, Y., Chen, Y., Qiu, J., Zhou, Z.*, Yao, P., Jiang, Q., Gong, Z., Coco, G., Townend, I. and Zhang, C., 2022. The role of geological mouth islands on the morphodynamics of back-barrier tidal basins. Earth Surface Dynamics, 10(1): 65-80, doi:10.5194/esurf-10-65-2022.
[8] 周曾, 陈雷, 林伟波, 罗锋, 陈雪, 张长宽, 2021. 盐沼潮滩生物动力地貌演变研究进展. 水科学进展, 32(03): 470-484.
[9] 龚政, 陈欣迪, 周曾*, 葛冉, 陈雪, 余锡平, 张长宽, 2021. 生物作用对海岸带泥沙运动的影响. 科学通报, 66(1): 53-62, doi:10.1360/TB-2020-0291.
[10] Zhou, Z., Liu, Q., Fan, D., Coco, G., Gong, Z., Möller, I., Xu, F., Townend, I. and Zhang, C., 2021. Simulating the role of tides and sediment characteristics on tidal flat sorting and bedding dynamics. Earth Surface Processes and Landforms, 46(11): 2163-2176, doi:10.1002/esp.5166.
[11] 陈雪, 贺强, 辛沛, 龚政, 周曾*, 张长宽. 2021. 河口海岸潮滩蟹类生物扰动行为过程研究进展. 海洋科学, 45(10): 113-122.
[12] 徐孟飘, 东培华, 马骏, 罗锋, 张长宽, 范代读, 周曾*, 2021. 大小潮作用对潮滩沉积物层理影响的数值模拟研究. 海洋学报. 2021,43(10):1–11, doi: 10.12284/hyxb2021125.
[13] Zhang, X., Li, H., Gong, Z., Zhou, Z., Dai, W., Wang, L. and Daramola, S., 2021. Method for UAV-based 3D topography reconstruction of tidal creeks. Journal of Geographical Sciences, 31(12): 1852-1872, doi:10.1007/s11442-021-1926-9.
[14] Zhang, H., Sun, T., Cao, H., Zhang, Y., Yang, W., Shao, D., Cui, B. and Zhou, Z., 2021. Movement of mud snails affects population dynamics, primary production and landscape heterogeneity in tidal flat ecosystems. Landscape Ecology, 36(12): 3493-3506, doi:10.1007/s10980-021-01322-7.
[15] Townend, I., Zhou, Z.*, Guo, L. and Coco, G., 2021. A morphological investigation of marine transgression in estuaries. Earth Surface Processes and Landforms, 46(3): 626-641, doi:10.1002/esp.5050.
[16] Wang, Y., Chen, J., Cai, H., Yu, Q*. and Zhou, Z.*, 2021. Predicting water turbidity in a macro-tidal coastal bay using machine learning approaches. Estuarine, Coastal and Shelf Science, 252: 107276, doi:10.1016/j.ecss.2021.107276.
[17] Dai, W., Li, H., Gong, Z., Zhou, Z., Li, Y., Wang, L., Zhang, C. and Pei, H., 2021. Self-organization of salt marsh patches on mudflats: Field evidence using the UAV technique. Estuarine, Coastal and Shelf Science, 262(2021): 107608, doi:10.1016/j.ecss.2021.107608.
[18] Zhou Z., Chen L.Y., Tao J.*, Gong Z., Guo L., van der Wegen M., Townend I., and Zhang C.K. (2020) The role of salinity in fluvio-deltaic morphodynamics: A long-term modelling study. Earth Surface Processes and Landforms, 45(3): 590-604, doi: 10.1002/esp.4757.
[19] Xu, F., Coco, G., Zhou, Z.*, Townend, I., Guo, L. and He, Q., 2020. A Universal Form of Power Law Relationships for River and Stream Channels. Geophysical Research Letters, 47(20), doi:10.1029/2020GL090493.
[20] 董楚宁, 周曾*, 陈文猛, 金秋, 钱钧 and 龚政, 2020. 不同降雨条件下生态护坡减流减沙效应对比研究. 江苏水利(04): 10-14+19
[21] Xie, D., Schwarz, C., Brückner, M.Z.M., Kleinhans, M.G., Urrego, D.H., Zhou, Z. and van Maanen, B., 2020. Mangrove diversity loss under sea-level rise triggered by bio-morphodynamic feedbacks and anthropogenic pressures. Environmental Research Letters, 15(11): 114033, doi:10.1088/1748-9326/abc122.
[22] Chen, L., Zhou, Z.*, Xu, F., Möller, I. and Zhang, C., 2020. Field Observation of Saltmarsh-Edge Morphology and Associated Vegetation Characteristics in an Open-Coast Tidal Flat. Journal of Coastal Research, 95(SI): 412-416, doi:10.2112/SI95-080.1.
[23] Zhao, K., Gong, Z., Zhang, K., Wang, K., Jin, C., Zhou, Z., Xu, F. and Coco, G., 2020. Laboratory Experiments of Bank Collapse: The Role of Bank Height and Near‐Bank Water Depth. Journal of Geophysical Research: Earth Surface, 125(5), doi:10.1029/2019JF005281.
[24] Dai, W., Li, H., Chen, X., Xu, F., Zhou, Z. and Zhang, C., 2020. Saltmarsh Expansion in Response to Morphodynamic Evolution: Field Observations in the Jiangsu Coast using UAV. Journal of Coastal Research, 95(SI): 433-437, doi:10.2112/SI95-084.1.
[25] Chen Lei, Zhou Zeng*, Xu Fan, Jimenez Mirian, Tao Jianfeng, and Zhang Changkuan, 2020. Simulating the Impacts of Land Reclamation and De-Reclamation on the Morphodynamics of Tidal Networks, Anthropocene Coasts, 3(1): 30-42, doi: 10.1139/anc-2019-0010.
[26] Fan Xu, Giovanni Coco, Jianfeng Tao, Zeng Zhou*, Changkuan Zhang, Stefano Lanzoni, Andrea D'Alpaos (2019) On the Morphodynamic Equilibrium of a Short Tidal Channel. Journal of Geophysical Research: Earth Surface, 124: 639-665, doi: 10.1029/2018JF004952
[27] Chen, X. D., Zhang, C. K., Paterson, D. M., Townend, I. H., Jin, C., Zhou, Z., Gong, Z., and Feng, Q. (2019) The effect of cyclic variation of shear stress on non‐cohesive sediment stabilisation by microbial biofilms: The role of “biofilm precursors”. Earth Surf. Process. Landforms, 44(7): 1471-1481, https://doi.org/10.1002/esp.4573.
[28] 龚政, 张岩松, 赵堃, 周曾, 张长宽, 2019. 风暴作用下淤泥质潮滩-潮沟系统地貌演变研究进展. 水利水电科技进展, 39(04): 75-84.
[29] 戴玮琦,李欢,龚政,张长宽,周曾(2019).无人机技术在潮滩地貌演变研究中的应用.水科学进展30(03): 359-372.
[30] 龚政, 黄诗涵, 徐贝贝, 朱思谕, 张岩松, 周曾, 2019. 江苏中部沿海潮滩对台风暴潮的响应. 水科学进展, 30(02): 243-254
[31] Geng L., Gong Z., Zhou Z., Lanzoni S. and D’Alpaos A. (2019) Assessing the relative contributions of the flood tide and the ebb tide to tidal channel network dynamics. Earth Surf. Process. Landforms, 44(7): 1471-1481, https://doi.org/10.1002/esp.4727.
[32] Zhao, K., Gong, Z., Xu, F., Zhou, Z., Zhang, C. K., Perillo, G. M. E., & Coco, G. ( 2019). The role of collapsed bank soil on tidal channel evolution: A process‐based model involving bank collapse and sediment dynamics. Water Resources Research, 55(11): 9051-9071, https://doi.org/10.1029/2019WR025514
[33] Tao, J., Wang, Z. B., Zhou, Z.*, Xu, F., Zhang, C., & Stive, M. J. F. ( 2019). A morphodynamic modeling study on the formation of the large‐scale radial sand ridges in the Southern Yellow Sea. Journal of Geophysical Research: Earth Surface, 124(7): 1742-1761. https://doi.org/10.1029/2018JF004866
[34] Zhou Z., Coco G., Townend I., Gong Z., Wang Z.B., and Zhang C.K. (2018) On the stability relationships between tidal asymmetry and morphologies of tidal basins and estuaries. Earth Surface Processes and Landforms, 43(9): 1943-1959, doi: 10.1002/esp.4366.
[35] Gong Z., Zhao K.*, Zhang C.K, Dai W., Coco G., Zhou Z. * (2018) The role of bank collapse on tidal creek ontogeny: A novel process-based model for bank retreat, Geomorphology. 311, 13-26, doi: 10.1016/j.geomorph.2018.03.016.
[36] Zhou Z., Chen L.Y., Townend I., Coco G., Friedrichs C., and Zhang C.K. (2018) Revisiting the relationship between tidal asymmetry and basin morphology: A comparison between 1D and 2D models. Journal of Coastal Research, Special Issue No. 85: 151-155, doi: 10.2112/SI85-031.1.
[37] 龚政,白雪冰,靳闯,赵堃,周曾,张长宽,基于植被和潮动力作用的潮滩剖面演变数值模拟,水科学进展,2018, 29(6): 877-886.
[38] 张长宽,徐孟飘,周曾*,龚政,康彦彦,李欢 (2018). 潮滩剖面形态与泥沙分选研究进展. 水科学进展,29(2): 269-282.
[39] Winterwerp J.C., Zhou Z., Battista G., Van Kessel T., Jagers B., Van Maren B., and Van der Wegen M. (2018). Efficient consolidation model for morphodynamic simulations in low SPM-environments. Journal of Hydraulic Engineering. 144(8): 04018055(1-14), doi: 10.1061/(ASCE)HY.1943-7900.0001477.
[40] Xu, F., Coco, G., Zhou, Z., Tao, J., & Zhang, C. (2017). A numerical study of equilibrium states in tidal network morphodynamics. Ocean Dynamics, 67(12), 1593-1607, doi: 10.1007/s10236-017-1101-0.
[41] Chen, X. D., Zhang, C. K., Zhou, Z., Gong, Z., Zhou, J. J., Tao, J. F., Paterson, D. M. & Feng, Q. (2017). Stabilizing effects of bacterial biofilms: EPS penetration and redistribution of bed stability down the sediment profile. Journal of Geophysical Research: Biogeosciences, 122(12): 3113-3125. doi:10.1002/2017JG004050.
[42] Gong, Z., Jin, C., Zhang, C., Zhou, Z., Zhang, Q., & Li, H. (2017). Temporal and spatial morphological variations along a cross-shore intertidal profile, Jiangsu, China. Continental Shelf Research, 144: 1-9, doi: 10.1016/j.csr.2017.06.009.
[43] Dai W., Li H., Zhou Z., Cybele S., Lu C., Zhao K., Zhang X., Yang H. and Li D. (2018) UAV photogrammetry for elevation monitoring of intertidal mudflats. Journal of Coastal Research, Special Issue for International Coastal Symposium 2018. Special Issue No. 85, pp. 236–240, doi: 10.2112/SI85-048.1.
[44] Tao, J., Xu, F., Yao, P., Zhou, Z., and Zhang, C., 2018. The variations of sediment transport patterns in the radial sand ridges along the Jiangsu coast, China over the last 30 years. In: Shim, J.-S.; Chun, I., and Lim, H.S. (eds.), Proceedings from the International Coastal Symposium (ICS) 2018 (Busan, Republic of Korea). Journal of Coastal Research, Special Issue No. 85, pp. 216–220, doi: 10.2112/SI85-044.1.
[45] Zhou Z., Coco G., Townend I., Olabarrieta M., van der Wegen M., Gong Z., D’Alpaos A., Gao S., Jaffe B. E., Gelfenbaum G., He Q., Wang Y., Lanzoni S., Wang Z. B., Winterwerp H. and Zhang C.K. (2017) Is “Morphodynamic Equilibrium” an oxymoron. Earth-Science Reviews, 165:257–267, doi: 10.1016/j.earscirev.2016.12.002.
[46] 龚政, 耿亮, 吕亭豫, 周曾, 严佳伟, 张长宽 (2017). 开敞式潮滩-潮沟系统发育演变动力机制——Ⅱ.潮汐作用. 水科学进展(02): 231-239.
[47] 龚政, 吕亭豫, 耿亮, 周曾, 徐贝贝, 张长宽 (2017). 开敞式潮滩-潮沟系统发育演变动力机制——Ⅰ.物理模型设计及潮沟形态. 水科学进展(01): 86-95.
[48] Chen, X. D., Zhang, C. K., Paterson, D. M., Thompson, C. E. L., Townend, I. H., Gong, Z., Zhou, Z. and Feng, Q. (2017), Hindered erosion: The biological mediation of non-cohesive sediment behaviour. Water Resources Research 53(6): 4787-4801, doi:10.1002/2016WR020105
[49] Townend I., Wang Z. B., Stive M., & Zhou Z. (2016). Development and extension of an aggregated scale model: part 1 – background to ASMITA. China Ocean Engineering, 30(4), 483-504, doi: 10.1007/s13344-016-0030-x.
[50] Townend I., Wang Z. B., Stive M., & Zhou Z. (2016). Development and extension of an aggregated scale model: part 2 — extensions to ASMITA. China Ocean Engineering, 30(5), 651-670, doi: 10.1007/s13344-016-0042-6
[51] 陆倩, 龚政, 周曾, 张长宽 (2016). 淤泥质海岸入海河口闸下港道河相关系. 水科学进展(05): 751-762.
[52] Zhou Z., van der Wegen M., Jagers B., and Coco G. (2016) Modelling the role of self-weight consolidation on the morphodynamics of accretional mudflats. Environmental Modelling & Software, 76, 167-181, doi: 10.1016/j.envsoft.2015.11.002.
[53] Xu F., Tao J.F., Zhou Z., Coco G., and Zhang C.K. (2016) Mechanisms underlying the regional morphological differences between the northern and southern radial sand ridges along the Jiangsu Coast, China. Marine Geology, 371, 1-17, doi:10.1016/j.margeo.2015.10.019
[54] Zhang Q., Gong Z., Zhang C. K., Zhou Z. and Townend I. (2016) Hydraulic and sediment dynamics at times of very shallow water on intertidal mudflats: the contribution of waves. Journal of Coastal Research, SI75, 507-511, doi: 10.2112/SI75-102.1
[55] Zhou Z., Ye Q., and Coco G. (2016) A one-dimensional biomorphodynamic model of tidal flats: Sediment sorting, marsh distribution, and carbon accumulation under sea level rise. Advances in Water Resources, 93, 288-302, doi: 10.1016/j.advwatres.2015.10.011.
[56] Zhou Z., Coco G., van der Wegen M., Gong Z., Zhang C.K., and Townend I. (2015) Modeling sorting dynamics of cohesive and non-cohesive sediments on intertidal flats under the effects of tides and wind waves. Continental Shelf Research, 104, 76-91, doi: 10.1016/j.csr.2015.05.010.
[57] Zhou Z., Coco G., Jiménez , M., Olabarrieta M., van der Wegen M., and Townend I. (2014) Morphodynamics of river-influenced back-barrier tidal basins: The role of landscape and hydrodynamic settings. Water Resources Research, 50(12), 9514-9535, doi:10.1002/2014WR015891.
[58] Jiménez M., Castanedo S., Zhou Z., Coco G., Medina R. and Rodriguez-Iturbe I. (2014) Scaling properties of tidal networks. Water Resources Research, 50(6), 4585-4602, doi:10.1002/2013WR015006.
[59] Zhou Z., Olabarrieta M., Stefanon L., D'Alpaos A., Carniello L. and Coco G. (2014) A comparative study of physical and numerical modeling of tidal network ontogeny. Journal of Geophysical Research: Earth Surface, 119(4), 892-912, doi:10.1002/2014JF003092.
[60] Zhou Z., Stefanon L., Olabarrieta M., D'Alpaos A., Carniello L. and Coco G. (2014) Analysis of the drainage density of experimental and modelled tidal networks. Earth Surface Dynamics, 2(1), 105-116, doi:10.5194/esurf-2-105-2014.
[61] Jiménez M., Castanedo S., Zhou Z., Coco G., Medina R. and Rodriguez-Iturbe I. (2014) On the sensitivity of tidal network characterization to power law estimation. Adv. Geosci., 39, 69-73, doi:10.5194/adgeo-39-69-2014.
[62] Coco G., Zhou Z., van Maanen B., Olabarrieta M., Tinoco R. and Townend I. (2013) Morphodynamics of tidal networks: advances and challenges. Marine Geology, 346, 1-16, doi:10.1016/j.margeo.2013.08.005.
[63] Zhou Z., de San Roman B. L. and Nicholls, R. (2013) An OpenMI-based combined model for alongshore sediment transport and shoreline change. Maritime Engineering, 166(4), 175 -186, doi:10.1680/maen.2012.14.
[64] Ying Zhang, Zeng Zhou, Liang Geng, Giovanni Coco, Jianfeng Tao, Changkuan Zhang, 2018. Simulating the formation of tidal channels along an open-coast tidal flat: The effects of initial perturbation. Coastal Engineering Proceedings, [S.l.], n. 36, p. papers.84, dec. 2018. ISSN 2156-1028. Available at: <https://icce-ojs-tamu.tdl.org/icce/index.php/icce/article/view/8664/7468>. Date accessed: 01 mar. 2019. doi: 10.9753/icce.v36.papers.84.
[65] Lei Chen, Zeng Zhou*, Mengpiao Xu, Fan Xu, Jianfeng Tao, Changkuan Zhang, 2018. Exploring the influence of land reclamation on sediment grain size distribution on tidal flats: A numerical study. Coastal Engineering Proceedings, [S.l.], n. 36, p. papers.85, dec. 2018. ISSN 2156-1028. Available at: <https://journals.tdl.org/icce/index.php/icce/article/view/8669>. Date accessed: 01 mar. 2019. doi: 10.9753/icce.v36.papers.85.
[66] Jin, C., Gong, Z., Zhang, C., Zhou, Z., & Li, H. (2015). The role of surface and subsurface processes on the morphodynamics of a vegetated mudflat. Proceedings of the Twenty-Fifth International Ocean and Polar Engineering Conference, 1317–1324.
[67] 张长宽,龚政,陈永平,陶建峰,康彦彦,周晶晶,周曾*(2017)潮滩演变研究进展及前沿问题.第十八届中国海洋(岸)工程学术讨论会论文集. 中国舟山, 759-766. (会议论文)
[68] Zhou Z., Coco G., Olabarrieta M. and van der Wegen M. (2013) On the transition between tide- and river-dominated back-barrier estuarine environments. in Zhaoyin Wang, Joseph Hun-Wei Lee, Jizhang Gao and Shuyou Cao (eds.), Proceedings of the 35th IAHR World Congress, Tsinghua University Press, Beijing. China.
[69] Zhou Z. and Lopez de San Roman B. (2011) Development and application of a combined model for longshore sediment transport and beach response. in Z. Wang, (ed.), Proceedings of the 7th IAHR symposium on River, Coastal and Estuarine Morphodynamics (RCEM 2011), Tsinghua Unviersity Press, Bejing, China.
专著和教材
《海洋资源开发与保护技术概论》,海洋出版社,参编。
《江苏沿海发展报告(2020)》,科学出版社,参编。
学位论文
Zhou Z. (2015). Tidal network morphodynamics: Processes, feedbacks and long-term evolution, University of Cantabria (ISBN书号:9788461735747),Tratamiento Grafico del Documento出版社,博士学位论文,http://hdl.handle.net/10902/6264,西班牙政府资助
Zhou Z. (2011). Feasibility study of a coupled numerical model for longshore sediment transport and beach response. University of Southampton, Delft University of Technology, Norwegian University of Science and Technology,欧盟Erasmus Mundus全额奖学金项目资助
代表性授权国家发明专利
[1] 一种潮滩-潮沟系统地貌演变物理模型试验系统及方法,ZL201610331381.0,中国,授权日:2017年11月28日,排名6/10
[2] 潮滩泥沙临界起动切应力原位测试装置及监测方法,ZL201610534494.0,中国,授权日:2018年7月24日,排名4/8
[3] 潮沟边壁冲刷及塌落过程的一维模拟方法,专利号:ZL201610466198.1,授权日:2019-03-12,排名5/7
[4] 一种潮沟系统地形识别处理方法,专利号:ZL201711032435.4,中国,授权日:2019-10-15,排名3/5
[5] 一种潮沟边壁侵蚀物理实验系统及方法,专利号:ZL201810594440.2,中国,授权日:2019-11-08,排名4/8
[6] 一种探究生物扰动下潮滩动力地貌的装置,专利号:ZL201910098549.1,中国,授权日:2020-09-28,排名2/9
代表性科研项目
1. 国家级青年人才计划项目,方向:河口海岸生物动力地貌学,2022-2024,主持
2. 南通市科技计划项目(长江大保护专项),南通沿海典型滩涂演变与生态修复方法研究(项目编号:MS12021083),2021.07-2023.06,主持
3. 江苏省优秀青年基金项目,滨海潮滩湿地地貌演变机制与生态修复(项目编号:BK20200077),2020.07-2023.06,主持
4. 国家自然科学基金面上项目,潮滩盐沼前缘地貌形态演变与系统状态转换机制研究(项目编号: 41976156),2020.01-2023.12,主持
5. 海洋地质国家重点实验室(同济大学)开放基金项目,河口海岸潮滩沉积层理形成与破坏机制研究(项目编号:MG201901),2019.01-2020.12,主持
6. 国家自然科学基金委员会与英国皇家学会合作交流项目,盐沼潮滩演变及恢复力:泰晤士河口与江苏海岸的对比性研究(项目编号:41811530302),合作单位:英国剑桥大学,2018.04-2020.03,主持
7. 国家自然科学基金青年项目,盐沼影响下潮沟系统形态特征及演变机理研究(项目编号:41606104),2017.01-2019.12,主持
8. 江苏省自然科学基金—青年基金项目,盐沼-潮滩系统多组分泥沙分选过程及地貌演变机制研究(项目编号:BK20160862),2016.07-2019.07,主持
9. 留学人员科技活动项目择优资助经费,潮滩湿地盐沼侵蚀-扩张机制与环境保护(项目编号:2016/B17051),2017.01-2018.12,主持
10. 中央高校基本科研业务费项目,潮滩多组分泥沙分选机制研究(项目编号:2016B00714), 2016.01-2018.12,主持
11. 国家自然科学重点国际(地区)合作与交流项目,多因子驱动下粉砂淤泥质潮滩演变机制及模拟(项目编号:51620105005),2017.01-2021.12,参与(排名2/11),课题负责人
12. 江苏省海洋科技创新项目重大专项(江苏省海洋与渔业局),基于海涂演变的湿地退化机理及修复技研究(HY2018-1),2018.04-2020.08,参与(排名7/37),课题负责人
13. 国家重点研发计划项目“长三角地区水安全保障技术集成与应用”课题,变化环境下河口海岸水安全保障关键技术研究与应用(项目编号:2016YFC0401505), 2016.07-2019.12,参与(排名8/23)
14. 江苏省水利科技重大攻关项目(江苏省水利厅),沿海典型垦区水生态系统构建与修复关键技术研究,2017.07-2020.06,项目经费120万元,参与,课题负责人
表彰奖励
2021.04 江苏省青蓝工程中青年学术带头人
2020.07 江苏省优秀青年基金获得者
2020.06 河海大学“青年岗位能手”
2018.01 河海大学“大禹学者计划”第三层次培养对象
2017.12 Elsevier-Advances in Water Resources期刊年度审稿突出贡献证书
2017.02 教育部,科学技术进步二等奖(排名:5/15): “南黄海潮滩演变与开发保护关键技术研究及应用”,编号2016-249,(龚政,陶建峰,张长宽,康彦彦,周曾,陈君,李欢,葛小平,王韫玮,丁贤荣,丁坚,张茜,靳闯,耿亮,徐凡)
2015.03 西班牙优秀博士论文(Cum Laude)
2014.12 Elsevier-Continental Shelf Research期刊年度审稿突出贡献证书
2012.03-2015.03 西班牙政府“引智”(Attracting Talents International)项目博士基金
2009.08-2011.07 欧盟Erasmus Mundus (CoMEM)硕士项目奖学金
2011.09 第七届IAHR-RCEM国际会议最佳报告奖
2011.07 荷兰Delft理工大学优秀硕士毕业生(Cum Laude)
学术兼职
(1) 学术期刊《Earth Surface Processes and Landforms》编委,2022.1
(2) 学术期刊《Anthropocene Coasts》 (加拿大科学出版社)副主编,2017.1~至今
(3) 学术期刊《Frontiers in Marine Science》 (中科院二区SCI) 副主编,Coastal Ocean Processes Section,2020.3
(4) 学术期刊《Water Science and Engineering》编委,2019.3~至今
(5) SCI学术期刊《Frontiers in Marine Science》副主编,2020.3~至今
(6) 河流、海岸与河口动力地貌学国际学术研讨会委员(Board member of IAHR-RCEM),2017.11~至今
联系方式
邮箱: zeng.zhou@hhu.edu.cn
本人一直致力于河口海岸动力学、潮滩生物动力地貌学与碳循环、海岸生态环境保护与生态修复等方向的科学研究与应用工作,欢迎业内学者和有志从事相关研究的学生与我联系,课题组科研氛围浓厚且随意,Let’s do some cool research together!
也欢迎感兴趣的老师和同学访问课题组的主页www.coastal-dynamics.net,尽管更新频次不算高:)
