刘林鹏

个人简介

中南大学机电工程学院副教授，硕士、博士研究生导师。于段吉安教授课题组团队从事科研教学工作。

湖南省芙蓉计划青年人才，博新计划获选人，中南大学升华优青、博士后，中南大学首届小米青年学者。

主要从事仿生功能表面、仿生机械量传感、柔性电子等领域的研究，以一作/通讯在Mat. Sci. Eng. R.、Adv. Mater. (ESI高被引论文)、Adv. Funct. Mater.、Chem. Eng. J. 等期刊发表论文20余篇。申请与授权国家发明专利10余项。主持国家重点研发项目子课题、国家自然科学青年基金等国家、省部级项目7项。获中南大学优秀本科毕业设计指导教师，中南大学教学质量优秀奖。

中国农业机械学会终身会员，中国农业机械学会地面机器系统分会委员会委员，国际仿生工程学会 (ISBE) 会员，极端服役性能精准制造重点实验室学术成员。eScience、Nano-Micro Letters、Nano Materials Science、Journal of Bionic Engineering、Advanced Bionics、Soft Science、Additive Manufacturing Frontiers期刊青年编委。

ق 研究方向：

1. 仿生功能表面
以自然界中具有高效感知、定向响应、黏附调控、减阻抗污和界面增强功能的生物表面为启发对象，研究其微纳结构特征、界面力学行为及多场耦合机制，构建具有特定功能的仿生表面体系。重点关注优异生物界面中的结构—功能关系，揭示微纳形貌、梯度构型、各向异性排列和层级拓扑对局域应力分布、界面接触演化、能量耗散以及机械信号传递的调控规律。进一步发展兼具应力整形、灵敏增强、界面适配与环境稳定性的仿生功能表面，为高性能传感、可控黏附/脱附、复杂界面信息采集和极端环境服役器件提供结构基础。

2. 柔性电子、机械量传感器

面向复杂场景下机械信息高精度获取需求，开展基于仿生启发的柔性压力、应变、振动、触觉等机械量传感器研究，以及多模态集成传感器件。围绕柔性材料在大变形、重复载荷和复杂耦合刺激下容易出现非线性、迟滞、漂移和一致性不足等关键问题，研究仿生结构设计、敏感层构筑、界面调控与信号转导协同机制，提升器件的各项性能。结合阵列化、系统集成、信号解耦、自校准和健康自诊断等策略，发展面向机器人灵巧手、可穿戴、植物表型、结构健康、航空航天装备状态感知等领域的高性能柔性传感器件与智能感知系统。

3. 飞秒激光微纳结构制造

围绕柔性材料和功能薄膜的高精度加工需求，开展飞秒激光与材料相互作用机理、微纳结构成形规律及器件制造方法研究。利用飞秒激光超短脉冲、低热影响和高空间分辨优势，构建适用于聚合物、弹性体、薄膜材料及复合功能材料的微纳加工新方法，实现仿生微纳结构和激光诱导功能图案的可控制备。重点研究飞秒激光参数窗口、结构一致性控制、表界面质量调节及多尺度结构的高效、高精度制造方法，推动飞秒激光在柔性电子、仿生传感、功能界面与集成器件制造中的应用。

ق 招生专业：

诚招物理、机械、电子、材料、通信、生物等专业的硕士研究生。

Email：linpengliu@csu.edu.cn

Phone/Wechat：18844198127

ق 教育与工作经历：

[6] 2023.9-至今: 中南大学 特聘副教授  |  机电工程学院  |  特聘副教授

[5] 2024.2-至今: The Hong Kong Polytechnic University (香港理工大学) 博士后 （合作导师：王钻开教授）  |  机械系

[4] 2021.8-2023.8: 中南大学 博士后（合作导师：段吉安教授）  |  机电工程学院

[3] 2016.9-2021.6: 吉林大学  |  仿生科学与工程  |  工学博士学位（导师：韩志武教授）

[2] 2019.10-2020.10: University of Berkeley, California, USA  |  Mechanical Engineering  |  Visiting student（Prof. Liwei Lin）

[1] 2012.9-2016.6: 吉林大学  |  农业机械化及其自动化 本科(学士)

ق 科研项目：

8. 国家重点研发项目子课题，2024YFF0504901, 2024.12-2029.11, 主持；

7. 国家自然科学基金青年项目，52205320, 2023-2025, 主持；

6. 湖南省芙蓉计划青年人才（青年托举类），2025QT-15, 2025-2027, 主持；

5. 湖南省自然科学基金青年项目，2023JJ40736, 2023-2025, 主持；

4. 湖南省教育厅优秀青年项目，25B0023, 2025, 主持；

3. 小米青年学者项目（中南大学首届），2023, 主持；

2. 中国博士后基金创新人才支持计划，BX20220353, 2022-2023，主持；

1. 中国博士后基金面上项目，2021M703632, 2021-2023，主持；

ق 学术网页：

https://scholar.google.com/citations?user=TkzmNJ0AAAAJ&hl=zh-CN

https://www.researchgate.net/profile/Linpeng-Liu

ق 代表性论文（五篇）：

5. Liu, L.^#; Niu, S.*; Zhang, J.; Mu, Z.; Li, J.; Li, B.; Meng, X.; Zhang, C.; Wang, Y.; Hou, T.; Han, Z.*; Yang, S.*; Ren, L. Bioinspired, Omnidirectional, and Hypersensitive Flexible Strain Sensors. Advanced Materials 2022, 34 (17), 2200823. (Q1, 中科院一区TOP，ESI Highly cited, IF: 32.086)   [Link]

4. Cao, P.; Wang, C.*; Niu, S.; Han, Z.; Liu, L.*; Duan, J. An ultrasensitive flexible force sensor with nature-inspired minimalistic architecture to achieve a detection resolution and threshold of 1 mN for underwater applications. Materials Science & Engineering R: Reports. 2024, 161: 100862. (Q1, 中科院一区TOP，IF: 31.6)  [Link]

3. Wang, J.; Liu, B.; Li, D.; Yuan, J.; Huang, D.; Zhang, C.; Song, W.; Wang, C.; Wang, J.; Liu, L.*; Han, Z.*; Ren, L. Fiber-shaped, stretchable strain sensors with high linearity by one-step injection molding for structural health monitoring. Advanced Functional Materials, 2025, 35(31): 2500701. (Q1, 中科院一区TOP，IF: 18.5) [Link]

2. Wu, H; Wang, C*; Liu, L*; Liu, Z; He, J; Zhang, C; Duan, J.  Bioinspired stretchable strain sensor with high linearity and superhydrophobicity for underwater applications. Advanced Functional Materials. 2025, 35(3): 2413552. (Q1, 中科院一区TOP，IF: 18.5)  [Link]

1. Liu, L.^#; Cai, Y.; Jiang, X.; Wang, J.*; Wang, C.*; Duan, J. A versatile surface micro structure design strategy for porous-based pressure sensors to enhance electromechanical performance. Chemical Engineering Journal. 2024, 490: 151529. (Q1, 中科院一区TOP，IF: 15.1)  [Link]

PUBLICATION LIST:

30. Wang, J.; Zheng, D.; Yan, Z.; Wu, M.; Hu, Y.; Liu, L.*; Zhang, Y.; Han, Z.; Qi, J. Biomimetic Coordination-Confined Cu⁺/Cu²⁺ Redox Interface with Self-Renewing Behavior Enables Ultrasensitive Uranyl Recognition. 2026. (Submitted)

29. Li, Z.^#; Liu, L.^#; Zhou, Z.; Cai, X.; Duan, L.; Dong, Y.; Hao, L.*; Wang, J.*; Jiang, R*. Balancing the Anti-Bacterial and Biocompatible Properties of Quaternary Ammonium Compounds Based Micro-patch for the Treatment of Deep Tissue Infection. 2026. (Submitted)

28. Wu, H.; Wang, C.*; Wang, Y.*; Liu, L.*; Duan, J. A Bioinspired Pressure Sensor with a Microgroove Structure for High-Frequency Dynamic Pressure Detection and Vibration Monitoring. 2026. (Submitted)

27. Cao, P.; Wang, C.*; Jia, X.; Han, W.; Liang, M.; Lin, N.; Yan, D.; Wang, J.*; Liu, L.*; Duan, J. Femtosecond-laser-engineered asymmetric bilayer microstructures for wide range, highly sensitive pressure sensing. 2026. (Submitted)

26. Liu, S.; Wu, H.; Chen, X.; Wang, X.; Peng, Z.; Liu, L.*; Wang, C.*; Jiang, X.*; Duan, J. A phenotypic wearable and synchronous environmental all-domain sensing system for precise monitoring of plant growth. 2026. (Submitted)

25. Liu, L.; Zhang, C.; Wang, J.; Wang, C.; Niu, S.*; Duan, J.; Han, Z.*; Ren, L. Bioinspired Wrinkle-Crack Interaction Engineering Enables Ultralinear Stretchable Strain Sensors with Ultralow Hysteresis. 2026. (Submitted)

24. Mou, Y.; Wang, C.; Jiang, X.; Wang, J.; Zhang, C.; Liu, L.*; Duan, J. Flexible Sensor with Material–Microstructure Synergistic Optimization for Wearable Physiological Monitoring. Materials, 2025, 18(15), 3707. (Q2, 中科院三区，IF: 3.2) [Link]

23. Wu, H.; Wang, C.*; Liu, L.*; Duan, J. Flexible FLIG-Based Temperature Sensor Enabled by Femtosecond Laser Direct Writing for Thermal Monitoring in Health Systems. Sensors, 2025, 25(15), 4643. (Q2，中科院二区，IF: 3.4)  [Link]

22. Mou, Y.; Wang, C.; Wang, S.; Liu, S.; Mu, Z.; Wang, J.; Liu, X.; Feng, X.; Liu, L.*; Duan, J. A Laser-Assisted Fabrication Metal Film Vibration Sensor for Achieving Omnidirectional Response. ACS Applied Electronic Materials, 2025, 7, 15, 7290–7300. (Q1, 中科院三区，IF: 4.4) [Link]

21. Wu, H.; Wang, C.*; Xu, X.; Mu, Z.; Wang, J.; Niu, S.; Liu, X.; Feng, X.; Liu, L.*; Duan, J.; Han, Z. A biomimetic metal diaphragm vibration sensor with high-frequency response based on a rigid-flexible hybrid design strategy. ACS Applied Electronic Materials, 2025, 7, 10, 4639–4648. (Q1, 中科院三区，IF: 4.4) [Link]

20. Wang, J.; Liu, B.; Li, D.; Yuan, J.; Huang, D.; Zhang, C.; Song, W.; Wang, C.; Wang, J.; Liu, L.*; Han, Z.*; Ren, L. Fiber-shaped, stretchable strain sensors with high linearity by one-step injection molding for structural health monitoring. Advanced Functional Materials, 2025, 35(31): 2500701. (Q1, 中科院一区TOP，IF: 18.5) [Link]

19. Zhang, Y; Quan, J; Liu, L*; Zhang, C; Duan, J.  A bioinspired, paper-based and soft-rigid sensor with wide frequency bandwidth for vibration monitoring. Materials Today Communications. 2025, 44, 111963. (Q2, 中科院三区，IF: 3.7)  [Link]

18. Mou, Y.; Wang, C.; Liu, S.; Liu, L.*; Duan, J. Flexible vibration sensors with omnidirectional sensing enabled by femtosecond laser-assisted fabrication. Polymers 2025, 17(2), 211. (Q1, 中科院二区，IF: 4.7)  [Link]

17. Wu, H; Wang, C*; Liu, L*; Liu, Z; He, J; Zhang, C; Duan, J.  Bioinspired stretchable strain sensor with high linearity and superhydrophobicity for underwater applications. Advanced Functional Materials. 2025, 35(3): 2413552. (Q1, 中科院一区TOP，IF: 18.5)  [Link]

16. Cao, P.; Wang, C.*; Niu, S.; Han, Z.; Liu, L.*; Duan, J. An ultrasensitive flexible force sensor with nature-inspired minimalistic architecture to achieve a detection resolution and threshold of 1 mN for underwater applications. Materials Science & Engineering R: Reports. 2024, 161: 100862. (Q1, 中科院一区TOP，IF: 31.6)  [Link]

15. Liu, L.^#; Cai, Y.; Jiang, X.; Wang, J.*; Wang, C.*; Duan, J. A versatile surface micro structure design strategy for porous-based pressure sensors to enhance electromechanical performance. Chemical Engineering Journal. 2024, 490: 151529. (Q1, 中科院一区TOP，IF: 15.1)  [Link]

14. Wang, C.; Quan, J.; Liu, L.*; Cao, P.; Ding, K.; Ding, Y.;  Jia, X.; Yan, D.; Lin, N; Duan, J. Rigid-soft hybrid paper-based flexible pressure sensor with ultrawide working range and frequency bandwidth. Journal of Materials Chemistry A, 2024, 12: 13994-14004. (Q1, 中科院二区TOP，IF: 11.9)  [Link]

13. Cao, P.; Wang, C.*; Liu, L.*; Ding, K.; Ding, Y.; Quan, J.; Jia, X.; Yan, D.; Lin, N.; Duan, J. Bioinspired low temperature Cu bonding interfaces with interlocked microstructures to achieve high robustness. Surfaces and Interfaces, 2024, 51: 104586. (Q1, 中科院二区，IF: 6.2)  [Link]

12. Zhang, Y; Yang, F; Cao, P; Liu, L*; Zhang, C; Duan, J. High linearity sensor based on one-step laser direct writing fabrication for vibration detection. ACS Applied Electronic Materials. 2024, 6, 9, 6940–6948 (Q2, 中科院三区，IF: 4.3)  [Link]

11. Zhang Y; Li, X; Fu J; Liu, L*; Zhang, C; Duan, J. . Low-cost and paper-based MEMS sensor for the vibration monitoring of shield cutter. Sensors. 2024, 24(16), 5349. (Q2，中科院二区，IF: 3.4)  [Link]

10. Cao, P; Wang, C; Mu, Z; Niu, S; Liu, X; Feng, X; Liu, L,*; Han, Z. Bioinspired microgroove’s geometry design and finite element analysis of bursting influence parameters for metal-based rupture diaphragms. Journal of Bionic Engineering. 2024, 22, 283-305. (Q1，中科院二区，IF: 4.9)  [Link]

9. Liu, L.^#; Niu, S.*; Zhang, J.; Mu, Z.; Li, J.; Li, B.; Meng, X.; Zhang, C.; Wang, Y.; Hou, T.; Han, Z.*; Yang, S.*; Ren, L. Bioinspired, Omnidirectional, and Hypersensitive Flexible Strain Sensors. Advanced Materials 2022, 34 (17), 2200823. (Q1, 中科院一区TOP，ESI Highly cited, IF: 32.086)   [Link]

8. Li, J.; Yao, Z.; Meng, X.; Zhang, C.; Sun, T.; Song, W.; Li, H.; Zhang, J.; Niu, S.; Liu, L.*; Han, Z.*; Ren, L. Paper-Based Sensor with Bioinspired Macrogrooves for Dual Pressure and Mechanical Strain Signal Detection. ACS Applied Nano Materials 2022, 5 (12), 18832–18841. (Q2, 中科院二区，IF: 5.9)  [Link]

7. Liu, L.^#; Meng, X.; Zhang, C.; Chen, Y.; Sun, T.; Lu, Z.; Zhang, J.; Niu, S.*; Han, Z.*; Duan, J.-A*. A Multifunctional Flexible Sensor with Coupling Bionic Microstructures Inspired by Nature. Journal of Materials Chemistry C 2022, 10 (31), 11296–11306. (Q1, 中科院二区，IF: 6.4)  [Link]

6. Cai, Y.#; Liu, L.*; Meng, X.; Wang, J.; Zhang, C.; Li, J.; Lu, Z.; Duan, J. A Broad Range and Piezoresistive Flexible Pressure Sensor Based on Carbon Nanotube Network Dip-Coated Porous Elastomer Sponge. RSC Advances 2022, 12 (52), 34117–34125. (Q2, 中科院二区，IF: 3.9)   [Link]

5. Wang, J.; Liu, L.; Yang, C.; Zhang, C.; Li, B.; Meng, X.; Ma, G.; Wang, D.; Zhang, J.; Niu, S.; Zhao, J.*; Han, Z.*; Yao, Z.*; Ren, L. Ultrasensitive, Highly Stable, and Flexible Strain Sensor Inspired by Nature. ACS Applied Materials & Interfaces 2022, 14 (14), 16885–16893. (Q1, 中科院二区TOP，IF: 9.5)  [Link]

4. Meng, X.; Sun, T.; Liu, L.; Zhang, C.; Zhao, H.; Wang, D.; Zhang, J.; Niu, S.*; Han, Z.*; Ren, L. Flexible Equivalent Strain Sensor with Ordered Concentric Circular Curved Cracks Inspired by Scorpion. ACS Applied Materials $ Interfaces 2022, 14 (25), 29441–29450.  (Q1, 中科院二区TOP，IF: 9.5)  [Link]

3. Liu, L.^#; Jiao, Z.; Zhang, J.; Wang, Y.; Zhang, C.; Meng, X.; Jiang, X.; Niu, S.*; Han, Z.*; Ren, L. Bioinspired, Superhydrophobic, and Paper-Based Strain Sensors for Wearable and Underwater Applications. ACS Applied Materials & Interfaces 2021, 13 (1), 1967–1978.  (Q1, 中科院二区TOP，IF: 10.383)  [Link]

2. Han, Z.; Liu, L.; Zhang, J.*; Han, Q.; Wang, K.; Song, H.; Wang, Z.; Jiao, Z.; Niu, S.*; Ren, L. High-Performance Flexible Strain Sensor with Bio-Inspired Crack Arrays. Nanoscale 2018, 10 (32), 15178–15186. [Q1, 中科院二区，Cover, IF: 6.7]  [Link]

1. Han, Z.; Liu, L.; Wang, K.; Song, H.; Chen, D.; Wang, Z.; Niu, S.; Zhang, J.*; Ren, L. Artificial Hair-Like Sensors Inspired from Nature: A Review. Journal of Bionic Engineering 2018, 15 (3), 409–434. [Q2, 中科院二区，Cover, IF: 4]  [Link]