姓  名

谈 笑

性  别

男

出生年月

1993.11

职  称

副研究员

毕业学校

美国斯蒂文斯理工学院

专  业

安全科学与工程

学 位

博士

联系电话

***

电子邮件

xiaotan@hhu.edu.cn

研究方向

安全检测与监控技术

光纤传感技术

管道结构损伤检测、评定与加固

智能基础设施

获奖情况

主要成果

谈笑，男，汉族，1993年11月生，安徽合肥人。2023年5月毕业于美国斯蒂文斯理工学院土木环境与海洋工程系，获土木工程博士学位。2024年1月入职河海大学水利水电学院，担任副研究员。

近年来，主要致力于管道安全监测与风险预警方向的研究。基于分布式光纤传感器，系统解决了任意应变场下结构应变传递效应定量评估-输水管道三维变形重建-管道变形耦合效应分离的科学难题，攻克了传感光纤发生界面滑移脱粘时测量管道结构裂缝的技术瓶颈，丰富了定量评估管道腐蚀质量损失的计算机理和预警腐蚀程度的监测方法，促进了对管道结构在多灾害情况下的智能诊断研究。目前，上述科研领域共发表权威SCI学术论文24篇，其中一作/通讯11篇（包括Automation in Construction、Mechanical System and   Signal Processing等中科院1区TOP期刊9篇），谷歌学术引用700余次，H因子14，成果得到了国内外知名学者的积极引用与评价。荣获国际先进传感网络技术和通信会议最佳研究员奖、第21届新泽西交通厅年度展会最佳海报奖、ASCE Journal of   Pipeline Systems Engineering and Practice优秀审稿人奖等荣誉奖励4项。现担任ASTM旗下SCI期刊Journal of Testing   and Evaluation编委和Developments   in the Built Environment等多个SCI期刊客座编辑。

代表性论著 (*代表通讯作者）:

[1] Tan, X., Bao, Y.*, Zhang, Q., Nassif,   H., and Chen, G., (2021), Strain transfer effect in distributed fiber   optic sensors under an arbitrary field, Automation in Construction,   124, p.103597. https://doi.org/10.1016/j.autcon.2021.103597   (IF: 9.6)

[2] Tan, X.,   Abu-Obeidah, A., Bao, Y.*; Nassif, N., and Nasreddine, W., (2021), Measurement   and visualization of strains and cracks in CFRP post-tensioned fiber   reinforced concrete beams using distributed fiber optic sensors, Automation in Construction, 124, p.103604. https://doi.org/10.1016/j.autcon.2021.103604   (IF: 9.6)

[3] Tan, X.,   Bao, Y.* (2021), Measuring crack width using a distributed fiber optic   sensor based on optical frequency domain reflectometry, Measurement: Journal of the International Measurement   Confederation, 172, p.108945. https://doi.org/10.1016/j.measurement.2020.108945   (IF: 5.2)

[4] Tan, X.,   Fan, L., Huang, Y. and Bao, Y.* (2021), Detection, visualization,   quantification, and warning of pipeline corrosion using distributed fiber   optic sensors, Automation in Construction,   132, p.103953. https://doi.org/10.1016/j.autcon.2021.103953   (IF: 9.6)

[5] Tan, X.,   Guo, P., Zou, X., and Bao, Y.* (2022), Buckling detection and shape   reconstruction using strain distributions measured from a distributed fiber   optic sensor, Measurement: Journal of the   International Measurement Confederation, 200, p.111625. https://doi.org/10.1016/j.measurement.2022.111625   (IF: 5.2)

[6] Tan, X.,   Mahjoubi, S., Zou, X., Meng, W., and Bao, Y.* (2023), Metaheuristic   inverse analysis on interfacial mechanics of distributed fiber optic sensors   undergoing interfacial debonding, Mechanical Systems and Signal   Processing, 200, p.110532. https://doi.org/10.1016/j.ymssp.2023.110532   (IF: 7.9)

[7] Tan, X.,   Mahjoubi, S., Zhang, Q., Dong, D. and Bao, Y.* (2022), A framework for   improving bridge resilience and sustainability through optimizing   high-performance fiber-reinforced cementitious composites, Journal of Infrastructure Preservation and Resilience,   3(1), pp.1-18. https://doi.org/10.1186/s43065-022-00067-0   (IF: 2.8)

[8] Tan, X.,   Poorghasem, S., Huang, Y., Feng, X., and Bao, Y.* (2024), Monitoring of   pipelines subjected to interactive bending and dent using distributed fiber   optic sensors, Automation in Construction,   160, p.105306. https://doi.org/10.1016/j.autcon.2024.105306   (IF: 9.6)

[9] Tan, X.,   Du, J., Zhang, Q., Meng, W., and Bao, Y.* (2024),  Monitoring   restrained shrinkage and cracks of ultra-high-performance concrete (UHPC)   using distributed fiber optic sensors, Construction and Building   Materials, 422, p.135789. https://doi.org/10.1016/j.conbuildmat.2024.135789   (IF: 7.4)

[10] Wu, X., He, J., Tian, J.*, Tan, X.*, Hu, S., Zheng Y., Wang, W., and   Zhang, W., (2023), Shear behaviors of engineered cementitious   composites to seawater sea-sand concrete (ECC-to-SSSC) interfaces cast using   3D-printed pre-grooving formwork: Mechanical properties, characterization,   and life-cycle assessment, Journal of BuildingEngineering, 78, p.107636. https://doi.org/10.1016/j.jobe.2023.107636   (IF: 6.7)

[11] Zhou, C., Tan, X.*, Zheng, Y., Wang, Y. and   Mahjoubi, S., (2024). Data-driven axial bearing capacity analysis of   steel tubes infilled with rubberized alkali-activated concrete. Advances in Structural Engineering,   p.13694332241268243. https://doi.org/10.1177/13694332241268243   (IF: 2.1)