李少琪，男，1995年3月生，博士，副教授。

邮箱：shaoqi@njtech.edu.cn

ORCID：https://orcid.org/0000-0001-6375-1096

研究方向

智能材料、结构振动控制、机器视觉

教育经历

(1) 2017.08 至 2021.02，澳大利亚，悉尼科技大学，土木工程，博士

(2) 2015.07 至 2017.07，澳大利亚，格里菲斯大学，土木工程，学士（一等荣誉）

(3) 2013.09 至 2017.07，中国矿业大学，土木工程，学士

工作经历

(1) 2022.04 至今，我校，太阳成集团tyc7111cc，副教授

(2) 2021.05 至 2021.11，澳大利亚，悉尼科技大学，博士后研究助理

(3) 2018.08 至 2021.11，澳大利亚，悉尼科技大学，教学助理

获奖经历

(1) 悉尼科技大学校长奖学金UTS President ‘s Scholarship

(2) 悉尼科技大学国际研究生奖学金UTS International Research Scholarship

(3) 格里菲斯大学奖章Griffith University Medal for Outstanding Academic Excellence

学术兼职

担任Frontiers in Materials 评审编辑以及Automation in Construction、Smart Materials and Structures、Journal of Intelligent Material Systems and Structures多个SCI期刊审稿人

发表论文

1. Wu, Y., Li, S.^*, Zhang, J., Li, Y.^*, Li, Y., & Zhang, Y. (2024). Dual attention transformer network for pixel-level concrete crack segmentation considering camera placement. Automation in Construction, 157, 105166. (IF 10.3)

2. Li, S., Li, Y.^*, & Li, J.^* (2021). Thixotropy of magnetorheological gel composites: Experimental testing and modelling. Composites Science and Technology, 214, 108996. (IF 8.528)

3. Li, S., Tian, T., Wang, H., Li, Y.^*, Li, J.^*, Zhou, Y., & Wu, J. (2020). Development of a four-parameter phenomenological model for the nonlinear viscoelastic behaviour of magnetorheological gels. Materials & Design, 194, 108935. (IF 7.991)

4. Li, S., Watterson, P. A., Li, Y^*., Wen, Q., & Li, J^*. (2020). Improved magnetic circuit analysis of a laminated magnetorheological elastomer device featuring both permanent magnets and electromagnets. Smart Materials and Structures, 29(8), 085054. (IF 3.585)

5. Li, S., Liang, Y., Li, Y.^*, Li, J.^*, & Zhou, Y. (2020). Investigation of dynamic properties of isotropic and anisotropic magnetorheological elastomers with a hybrid magnet shear test rig. Smart Materials and Structures, 29(11), 114001. (IF 3.585)

6. Tian, Z., Li, Y., Li, S., Vute, S., & Ji, J. (2022). Influence of particle morphology and concentration on the piezoresistivity of cement-based sensors with magneto-aligned nickel fillers. Measurement, 187, 110194.

7. Tian, Z., Li, S., & Li, Y. (2022). Enhanced sensing performance of cement-based composites achieved via magnetically aligned nickel particle network. Composites Communications, 29, 101006.

8. Xu, T., Li, Y., Lai, T., & Li, S. (2022). H 2 and H∞ optimal designs of tuned inerter dampers for base motion excited structures with inherent damping. Journal of Vibration and Control, 10775463221102254.

9. Tian, Z., Li, S., & Li, Y. (2021). Aligning conductive particles using magnetic field for enhanced piezoresistivity of cementitious composites. Construction and Building Materials, 313, 125582.

10. Huang, J., Li, S., Zhou, Y., Xu, T., Li, Y., Wang, H., & Wang, S. (2021). A heavy-duty magnetorheological fluid mount with flow and squeeze model. Smart Materials and Structures, 30(8), 085012.

11. Wang, H., Chang, T., Li, Y., Li, S., Zhang, G., & Wang, J. (2021). Field–Frequency-Dependent Non-linear Rheological Behavior of Magnetorheological Grease Under Large Amplitude Oscillatory Shear. Frontiers in Materials, 99.

12. Wang, H., Chang, T., Li, Y., Li, S., Zhang, G., Wang, J., & Li, J. (2021). Characterization of nonlinear viscoelasticity of magnetorheological grease under large oscillatory shear by using Fourier transform-Chebyshev analysis. Journal of Intelligent Material Systems and Structures, 32(6), 614-631.

13. Yu, Y., Royel, S., Li, Y., Li, J., Yousefi, A. M., Gu, X., ... & Li, H. (2020). Dynamic modelling and control of shear-mode rotational MR damper for mitigating hazard vibration of building structures. Smart Materials and Structures, 29(11), 114006.

14. Yu, Y., Li, J., Li, Y., Li, S., Li, H., & Wang, W. (2019). Comparative investigation of phenomenological modeling for hysteresis responses of magnetorheological elastomer devices. International journal of molecular sciences, 20(13), 3216.