赵玄烈

赵玄烈，工学博士，哈尔滨工程大学船舶工程学院副教授，博士生导师，硕士生导师，葡萄牙里斯本大学访问学者，深海工程装备技术工信部重点实验室副主任，海洋工程技术研究所副所长。主要研究方向：波浪与结构物相互作用、海洋可再生能源开发利用、多功能海洋（岸）工程结构设计理论。承担国家重点研发计划课题、政府间国际科技合作重点专项（任务）、国家自然科学基金项目（面上和青年）等多项课题。入选第六届中国科协“青年人才托举工程”项目，曾获得国际海洋和极地工程协会（ISOPE）青年力学奖、辽宁省优秀博士论文奖、黑龙江省高校科学技术奖等。发表学术论文40余篇，被引1000余次，授权发明专利9项，担任黑龙江省工业和信息化厅专家（海洋工程装备制造领域）、China Ocean Engineering青年编委，多次担任国际会议/学术刊物的科学委员会委员/分会主席/客座主编，多次受邀在国内外知名学术会议上作大会/特邀/主题报告，担任20余个国内外知名期刊和会议的审稿人。

大连理工大学，港口、海岸及近海工程，2015.09-2019.01 （导师：宁德志、康海贵）

部分科研项目如下：
1 水深突变条件下阵列多气室OWC波能装置水动力特性研究，2023.1-2026.12，国家自然科学基金面上项目，负责人
2 面向2050年的世界海洋经济与装备创新发展战略研究， 2022.1-2023.12，工信部，参与（负责海洋可再生能源部分）
3 波浪能、潮流能技术综合评估方法合作研究（子任务），2019.12-2022.11，政府间国际科技创新合作重点专项，负责人
4 近岸反射条件下浮式防波堤-阵列波浪能装置集成系统水动力特性研究，2021.1-2023.12，国家自然科学基金青年科学基金项目，负责人
5 浮式防波堤-阵列波浪能装置集成系统水动力特性研究，中国博士后科学基金面上资助，2019.12-2021.7，负责人
6 大连理工大学海岸和近海工程国家重点实验室基金项目，自由表面波的全反射与全透射现象研究，2019.7-2021.6，负责人

 1 第37届中国高等学校电力系统及其自动化专业学术年会（论坛）， 2022.10， 中国杭州，特邀报告
2 第三届波浪能气动式一体化技术研讨会，大连（线上）， 2022.7， 中国大连，特邀报告
3 5th International Conference on Renewable Energies Offshore，2022.11，LISBON, PORTUGAL（online），分组报告
4 世界海洋科技大会海洋能青年科学家论坛，2021.11，中国青岛，特邀报告
5 极端气候条件下海岸带灾害预警与减灾研究中英双边研讨会，2021.11，中国镇江，主题报告
6 欧洲波浪能和潮流能会议（EWTEC），2021.10，Plymouth, UK（online），分组报告
7 2021年港口、航道、海岸和海洋工程中青年学术研讨会，2021.6，中国青岛，分组报告

一级学科：水利工程；硕士研究生

《港口水工建筑物》

《波浪对近海工程结构的作用》
《论文写作指导》

全国研究生教育评估监测专家库专家
中国造船工程学会会员
20余个国内外知名期刊和会议的审稿人

文章所发表的刊物包括能源类TOP期刊：Renewable and Sustainable Energy Reviews （IF：14.98）、Renewable Energy、Energy等；海洋工程类TOP期刊：Applied Ocean Research、Ocean Engineering等。论著详见Scopus主页：https://www.scopus.com/authid/detail.uri?authorId=57188976802

部分论文如下：

1 Zhang, Y. , Zhao, X. (通讯作者), , Geng, J. , Göteman, M. , & Tao, L. Wave power extraction and coastal protection by a periodic array of oscillating buoys embedded in a breakwater. Renewable Energy, 2022.
2 Zhao X, Zou Q, Geng J, Zhang Y, Wang Z (2022) Influences of wave resonance on hydrodynamic efficiency and loading of an OWC array under oblique waves. Applied Ocean Research 120: 103069.
3 Zhao X, Xue R, Geng J, Göteman M (2021) Analytical investigation on the hydrodynamic performance of a multi-pontoon breakwater-WEC system. Ocean Engineering 220: 108394.
4 Zhao X, Du X, Li M, Göteman M (2021) Semi-analytical study on the hydrodynamic performance of an interconnected floating breakwater-WEC system in presence of the seawall. Applied Ocean Research 109: 102555.
5 Zhao X, Zhang Y, Li M, Johanning L (2021) Experimental and analytical investigation on hydrodynamic performance of the comb-type breakwater-wave energy converter system with a flange. Renewable Energy 172: 392-407.
6 Zhao X, Zhang L, Li M, Johanning L (2021) Experimental investigation on the hydrodynamic performance of a multi-chamber OWC-breakwater. Renewable and Sustainable Energy Reviews 150: 111512.
7 Zhang Y, Zhao X(通讯作者), Geng J, Tao L (2021) A novel concept for reducing wave reflection from OWC structures with application of harbor agitation mitigation/coastal protection: Theoretical investigations. Ocean Engineering 242: 110075.
8 Zhang Y, Li M, Zhao X(通讯作者), Chen L (2020) The effect of the coastal reflection on the performance of a floating breakwater-WEC system. Applied Ocean Research 100
9 Zhao X, Zhang Y, Li M, Johanning L (2020) Hydrodynamic performance of a Comb-Type Breakwater-WEC system: An analytical study. Renewable Energy 159: 33-49.
10 Zhao XL, Ning DZ, Liang DF (2019) Experimental investigation on hydrodynamic performance of a breakwater-integrated WEC system. Ocean Engineering 171: 25-32.
11 Zhao XL, Ning DZ, Zou QP, Qiao DS, Cai SQ (2019) Hybrid floating breakwater-WEC system: A review. Ocean Engineering 186: 106126.
12 Zhao X, Ning D (2018) Experimental investigation of breakwater-type WEC composed of both stationary and floating pontoons. Energy 155: 226-233.
13 Ning D, Zhao X, Zhao M, Hann M, Kang H (2017) Analytical investigation of hydrodynamic performance of a dual pontoon WEC-type breakwater. Applied Ocean Research 65: 102-111.
14 Ning DZ, Zhao XL, Teng B, Johanning L (2017) Wave diffraction from a truncated cylinder with an upper porous sidewall and an inner column. Ocean Engineering 130: 471-481.
15 Ning D, Zhao X, Göteman M, Kang H (2016) Hydrodynamic performance of a pile-restrained WEC-type floating breakwater: An experimental study. Renewable Energy 95: 531-541.
16 Zhao X, Ning D, Göteman M, Kang H (2017) Effect of the PTO damping force on the wave pressures on a 2-D wave energy converter. Journal of Hydrodynamics, Ser. B 29(5): 863-870.
17 Ning, D. , Zhao, X. , Zhao, M. , & Kang, H. Experimental investigation on hydrodynamic performance of a dual pontoon–power take-off type wave energy converter integrated with floating breakwaters. Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment, 2018: 880862661.

1. 中国科协青年人才托举工程，2021年
2. 辽宁省优秀博士论文奖，2021年
3. 辽宁省高等学校优秀毕业生, 2019年
4. ISOPE颁发的青年力学奖，2018年

1. 黑龙江省高校科学技术奖，2021年
2. 第六届全国大学生水利创新设计大赛一等奖（指导老师），2019年7月

[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. (Advisor), 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 analysis of the hydrodynamic characteristics of a convergent wave channel. Journal of Harbin Engineering University, 2021, 42(01): 42-48.
[24] Zhao, X.L., Ning, D.Z., Kang, H.G., Chen, B. Analytical study on the hydrodynamic characteristics of a vertically submerged cylinder with an upper porous structure under wave action. Engineering Mechanics, 2017(12): 239-247.