赵玄烈

Dr. Xuanlie Zhao is an Associate Professor at the College of Shipbuilding Engineering, Harbin Engineering University, China. He is the visiting scholar at the Centre for Marine Technology and Ocean Engineering (CENTEC), Instituto Superior Técnico, University of Lisbon, Portugal. He holds the role of the Deputy Director at the Ministerial-level Key Laboratory of Deep-sea Engineering Equipment and Technology, China. His interests revolve around wave-structure interactions, offshore renewable energy system, and multi-functional marine structures. As a Principal Investigator, he has successfully led five projects, including two projects funded by the National Natural Science Foundation of China (NSFC). He has also actively participated in several key projects sponsored by the Ministry of Science and Technology (MOST), Ministry of Industry and Information Technology (MIIT), and various industrial partners. He has authored over 40 peer-reviewed papers, which have garnered more than 800 citations. Furthermore, he has been recognized as a reviewer for over 20 reputable journals and conferences. He was selected for the 6th Young Elite Scientist Sponsorship Program by the China Association for Science and Technology (CAST) in 2020. He is the member (youth) of the editorial board of 2 Journals and the organization committee member of several international conferences.

Ph.D. in Port, Coastal, and Offshore Engineering, Dalian University of Technology, 2015.09-2019.01 (Supervisors: Ning Dezhi and Kang Haigui)

[1] Zhao, X.L., Li, Y., Zou, Q.P., Han, D.F., Geng, J., 2022. Long wave absorption by a dual-purpose Helmholtz resonance OWC breakwater. Coast. Eng. 178, 104203. (SCI Q1, IF = 5.427)
[2] Zhao, X.L., Zhang, L.D., Li, M.W., Johanning, L., 2021. Experimental investigation on the hydrodynamic performance of a multi-chamber OWC-breakwater. Renew. Sustain. Energy Rev. 150, 111512. (SCI Q1, IF = 16.799)
[3] Zhang, Y., Zhao, X.L. (Corresponding author), Geng, J., Göteman, M., Tao, L.B., 2022. Wave power extraction and coastal protection by a periodic array of oscillating buoys embedded in a breakwater. Renew. Energ. 190, 434–456. (SCI Q1, IF = 8.634)
[4] Zhao, X.L., Zhang, Y., Li, M.W., Johanning, L., 2021. Experimental and analytical investigation on hydrodynamic performance of the comb-type breakwater-wave energy converter system with a flange. Renew. Energ. 172, 392–407. (SCI Q1, IF = 8.634)
[5] Zhao, X.L., Zhang, Y., Li, M.W., Johanning, L., 2020. Hydrodynamic performance of a Comb-Type Breakwater-WEC system: An analytical study. Renew. Energ. 159, 33–49. (SCI Q1, IF = 8.634)
[6] Zhou, J., Zhao, X. (Corresponding author), Zang, J., Geng, J., Sun, S., 2023. Wave power extraction by an oscillating water column array embedded in comb-type breakwaters: Performance analysis and hydrodynamic mechanism, Phys. Fluids, 35(7), 077110
[7] Xuanlie Zhao, Fangjun Xue, Linghao Chen, Malin Göteman, Duanfeng Han (Corresponding author), Jing Geng, Sulong Sun, 2023. Hydrodynamic analysis of a floating platform coupled with an array of oscillating bodies, Ocean Eng.
[8] Zhao, X.L., Ning, D.Z., Zou, Q.P., Qiao, D.S., Cai, S.Q., 2019. Hybrid floating breakwater-WEC system: A review. Ocean Eng. 186, 106126. (JCR Q1, IF = 4.372, 100+ citations)
[9] Ning, D.Z. (Advisor), Zhao, X.L., Göteman, M., Kang, H.G., 2016. Hydrodynamic performance of a pile-restrained WEC-type floating breakwater: An experimental study. Renew. Energ. 95, 531–541. (SCI Q1, IF = 8.634, 100+ citations)
[10] Zhao, X.L., Ning, D.Z., Liang, D.F., 2019. Experimental investigation on hydrodynamic performance of a breakwater-integrated WEC system. Ocean Eng. 171, 25–32. (JCR Q1, IF = 4.372, 60+ citations)
[11] Zhao, X.L., Ning, D.Z., 2018. Experimental investigation of breakwater-type WEC composed of both stationary and floating pontoons. Energy 155, 226–233. (SCI Q1, IF = 8.857, 50+ citations)
[12] Ning, D.Z. , Zhao, X.L., Zhao, M., Hann, M., Kang, H.G., 2017. Analytical investigation of hydrodynamic performance of a dual pontoon WEC-type breakwater. Appl. Ocean Res. 65, 102–111. (JCR Q2, IF = 3.761, 50+ citations)
[13] Li, Y., Zhao, X.L. (Corresponding author), Zou, Q.P., Geng, J., 2022. Hydrodynamic performance of a dual-chamber Oscillating Water Column array under oblique waves. Phys. Fluids 34, 117112.
[14] Li, Y., Zhao, X.L. (corresponding author), Geng, J., Mackay, E., Johanning, L., 2022. Wave scattering by a vertical cylinder with a submerged porous plate: Further analysis. Ocean Eng. 259, 111711.
[15] Zhao, X.L., Zou, Q.P., Geng, J., Zhang, Y., Wang, Z.J., 2022. Influences of wave resonance on hydrodynamic efficiency and loading of an OWC array under oblique waves. Appl. Ocean Res. 120, 103069.
[16] Zhao, X.L., Xue, R., Geng, J., Göteman, M., 2021. Analytical investigation on the hydrodynamic performance of a multi-pontoon breakwater-WEC system. Ocean Eng. 220, 108394.
[17] Zhao, X.L., Du, X., Li, M.W., Göteman, M., 2021. Semi-analytical study on the hydrodynamic performance of an interconnected floating breakwater-WEC system in presence of the seawall. Appl. Ocean Res. 109, 102555.
[18] Zhang, Y., Zhao, X.L. (corresponding author), Geng, J., Tao, L.B., 2021. A novel concept for reducing wave reflection from OWC structures with application of harbor agitation mitigation/coastal protection: Theoretical investigations. Ocean Eng. 242, 110075.
[19] Zhang, Y., Li, M.W., Zhao, X.L. (corresponding author), Chen, L.F., 2020. The effect of the coastal reflection on the performance of a floating breakwater-WEC system. Appl. Ocean Res. 100, 102117.
[20] Ning, D.Z. (supervisor), Zhao, X.L., Zhao, M., Kang, H.G., 2018. Experimental investigation on hydrodynamic performance of a dual pontoon–power take-off type wave energy converter integrated with floating breakwaters. Proc. Institution Mech. Eng. Part M J: Eng. Marit. Environ. 233, 991–999.
[21] Ning, D.Z. (supervisor), Zhao, X.L., Teng, B., Johanning, L., 2017. Wave diffraction from a truncated cylinder with an upper porous sidewall and an inner column. Ocean Eng. 130, 471–481.
[22] Zhao, X.L., Ning, D.Z., Göteman, M., Kang, H.G., 2017. Effect of the PTO damping force on the wave pressures on a 2-D wave energy converter. J. Hydrodynamics Ser. B 29, 863–870.
[23] Cui, L., Geng, J., Zhao, X.L. (corresponding author), Zhang, Y. Analytical solution to hydrodynamic characteristics of
a wave-gathering channel. Journal of Harbin Engineering University, 2021, 42(01): 42-48. （in chinese）
[24] Zhao, X.L., Ning, D.Z., Kang, H.G., Chen, B. ANALYTICAL STUDY ON THE VERTICAL HYDRODYNAMICS OF A TRUNCATED CYLINDER WITH UPPER POROUS WALL AND INNER COLUMN. Engineering Mechanics, 2017(12): 239-247.（in chinese）