职称:副教授,博士生导师
招生专业:学术型博士(力学)、学术型硕士(力学)、专业硕士(土木水利)
地址:广州市天河区五山路381号华南理工大学交通大楼3楼304室
电话:020-87111030-3304(办)
核心研究方向和兴趣:智能可穿戴结构与系统、绿色能量收集技术、柔性传感技术、柔性驱动器、软物质力学、及它们在运动、健康、医疗领域的应用。
个人简介
杨宝,男,汉族,广东人,中共党员。2007年6月毕业于华南理工大学工程力学,获学士学位;2012年12月毕业于华南理工大学固体力学专业,师从汤立群教授,获博士学位(校优博)。随后2013年至2021年,工作于香港理工大学纺织与服装学系及智能可穿戴中心,师从陶肖明教授(国际纺织学会荣誉院士、获美国纤维学会最高个人奠基者奖和第十三届光华工程科技奖等),历经Postdoc Fellow/Research Associate/Research Fellow,一致从事智能可穿戴能源收集系统、柔性精确传感系统、智能织物等技术的基础研究以及它们在运动、健康、医疗领域应用。曾作为骨干参与申请和执行国家自然科学基金、国家重点研发计划、香港创新及科技和香港基础研究基金等项目10余项,项目总经费超五千万港币。通过引进计划,于2021年6月入职华南理工大学力学系,担任副教授至今。
杨宝博士以力学为出发点开展研究,将力学与材料学、光学、电学、热学、纺织以及医学等领域的特点进行融合,实现优势互补,获得更合理、更高效的智能可穿戴结构与系统,在可穿戴能源工作机理和精确压力传感方面取得了创新性研究成果。现发表期刊(SCI)论文20余篇,其中JCR Q1区16篇,为Smart Materials and Structures,Fibers and Polymers, Mechanics of Advanced Materials and Structures等SCI期刊审稿人。
代表性成果
[1] Bao Yang, Wei Zeng, Zehua Peng, Shirui Liu, Ke Chen, and Xiaoming Tao*. 2016. A Fully Verified Theoretical Analysis of Contact-Mode Triboelectric Nanogenerators as a Wearable Power Source, Advanced Energy Materials, 6(16):1600505.
[2] Bao Yang, Ying Xiong, Kitming Ma, and Xiaoming Tao*. 2020. Recent advances in wearable textile‐based triboelectric generator systems for energy harvesting from human motion. Eco Mat, 2(4): e12054.
[3] Bao Yang, Xiaoming Tao*, and Zehua Peng. 2019. Upper limits for output performance of contact-mode triboelectric nanogenerator systems, Nano Energy, 57:66-73.
[4] Xi Wang#, Bao Yang#, Qiao Li, Fei Wang, Xiaoming Tao*. 2021. Modeling the stress and resistance relaxation of conductive composites-coated fabric strain sensors. Composites Science and Technology, 204:108645.
[5] Rong Yin#, Bao Yang#, Xunjiao Ding, Su Liu, Wei Zeng, Jun Li, Su Yang, and Xiaoming Tao*. 2020. Wireless Multistimulus‐Responsive Fabric‐Based Actuators for Soft Robotic, Human–Machine Interactive, and Wearable Applications, Advanced Materials Technologies, 2000341.
[6] Bao Yang#, Xi Wang#, Ying Xiong, Shirui Liu, Xia Guo, and Xiaoming Tao*. 2020. Smart Bionic Morphing Leg Mannequin for Pressure Assessment of Compression Garment, Smart Materials and Structures, 29(5): 055041.
[7] Bao Yang, Liqun Tang*, Yiping Liu, Zejia Liu, Zhenyu Jiang and Daining Fang, 2013. Localized Deformation in Aluminium Foam during Middle Speed Hopkinson Bar Impact Tests, Materials Science and Engineering A, 560:734-743.
[8] Bao Yang, Su Liu, Xi Wang, Rong Yin, Ying Xiong, and Xiaoming Tao*. 2019. Highly Sensitive and Durable Structured Fibre Sensors for Low-Pressure Measurement in Smart Skin. Sensors, 19(8): 1811.
[9] Bao Yang, Zejia Liu, Liqun Tang, Zhenyu Jiang and Yiping Liu*, 2015. Mechanism of the Strain Rate Effect of Metal Foams with Numerical Simulations of 3D Voronoi Foams during the Split Hopkinson Pressure Bar Tests, International Journal of Computational Methods, 12(04):1540010.
[10] Bao Yang, Liqun Tang*, Yiping Liu, Zejia Liu, Zhenyu Jiang and Daining Fang, 2014. The Deformation Measurement and Analysis on Meso-Structure of Aluminium Foams during SHPB Tests, Journal of Testing and Evaluation, 42(3):621-628.
[11] 杨宝,汤立群*,刘逸平,刘泽佳, 黄小清,张纯禹和魏志强,2012.冲击条件下泡沫铝的细观变形特征分析, 爆炸与冲击, 32(4): 399-403. (EI)
[12] Jianliang Gong, Bingang Xu*, Yujue Yang, Mengjie Wu, Bao Yang. 2020. An Adhesive Surface Enables High-Performance Mechanical Energy Harvesting with Unique Frequency-Insensitive and Pressure-Enhanced Output Characteristics, Advanced Materials, 32(14): 1907948.
[13] Jidong Shi, Su Liu, Lisha Zhang, Bao Yang, Lin Shu, Ying Yang, Ming Ren, Yang Wang, Jiewei Chen, Weu Chen*, Yang Chai*, Xiaoming Tao*. 2019. Smart Textile‐Integrated Microelectronic Systems for Wearable Applications, Advanced Materials,32(5):1901958.
[14] Song Chen, Xiaoming Tao*, Wei Zeng, Bao Yang, and Songmin Shang. 2017. Quantifying Energy Harvested from Contact-Mode Hybrid Nanogenerators with Cascaded Piezoelectric and Triboelectric Units, Advanced Energy Materials, 7(5): 1601569, P.1-9.
[15] Su Liu, Kitming Ma, Bao Yang, Heng Li, Xiaoming Tao*. 2021.Textile Electronics for VR/AR Applications. Advanced Functional Materials, 2007254.
[16] Shirui Liu, Wei Zheng, Bao Yang, and Xiaoming Tao*. 2018. Triboelectric charge density of porous and deformable fabrics made from polymer fibers. Nano Energy,53: 383-390.
[17] Lisha Zhang, Bao Yang, Shuping Lin, Tao Hua, Xiaoming Tao*. 2020. Predicting performance of fiber thermoelectric generator arrays in wearable electronic applications. Nano Energy, 105117.
[18] Su Yang,Su Liu, Xujiao Ding, Bo Zhu, Jidong Shi, Bao Yang, Shirui Liu Wei Chen, Xiaoming Tao*. 2021. Permeable and washable electronics based on polyamide fibrous membrane for wearable applications. Composites Science and Technology, 207:108729.
[19] Jian Song, Bao Yang, Wei Zeng, Zehua Peng, Shuping Lin, Jun Li and Xiaoming Tao*. 2018. Highly Flexible, Large-Area and Facile Textile-Based Hybrid Nanogenerator with Cascaded Piezoelectric and Triboelectric Units for Mechanical Energy Harvesting, Advanced Materials Technologies, 3(6):1800016.
[20] Xi Wang, Bao Yang, Li Qiao, Xia Guo, and Xiaoming Tao*. 2020. Parametric Modeling the Human Calves for Evaluation and Design of Medical Compression Stockings. Computer Methods and Programs in Biomedicine, 105515.
[21] Xi Wang, Xiaoming Tao*, RCH So, Lin Shu, Bao Yang, and Ying Li. 2016. Monitoring Elbow Isometric Contraction by Novel Wearable Fabric Sensing Device, Smart Materials and Structures, 25(12):125022.
[22] Chunyu Zhang, Liqun Tang, Bao Yang, Lue Zhang, Xiaoqing Huang, and Daining Fang, 2013. Meso-mechanical study of collapse and fracture behaviors of closed-cell Metallic foams, Computational Materials Science, 79:45-51.
[23] Lohan Peng*, Huiliang Zhang, Bao Yang, Liqun Tang, Philip Hemmer, Hong Liang, 2010. Stress-Induced Nanostructures through Laser-Assisted Scanning Probe Nanolithography, The Journal of Scanning Microscopies, 32 (5): 327-335.
更多成果请参见:
ORCID:https://orcid.org/0000-0003-3638-0212
ResearchGate:https://www.researchgate.net/profile/Bao-Yang-10
Google Scholar:https://scholar.google.com/citations?user=2jONmJkAAAAJ&hl=en