邸江涛
- 单位:中国科学院苏州纳米技术与纳米仿生研究所
- 地址:江苏省苏州工业园区若水路398号
- 电话:0512—62873515
- 邮箱:jtdi2009@sinano.ac.cn
个人简历/Personal resume
邸江涛,中国科学院苏州纳米所研究员,博士生导师。2008年毕业于江苏科技大学获学士学位,2013年毕业于中国科学院大学获博士学位,2013-2016年间在美国德克萨斯州大学达拉斯分校任研究助理,2016年入职中国科学院苏州纳米所,任项目研究员(2016)、研究员(2019)。入选中国科学院“率先行动”引才计划(择优支持,2019)、江苏省双创人才(2018)、江苏省333工程(2018)、苏州工业园区金鸡湖高层次人才(2018)等支持,获部级科技奖一等奖(3/10,2020),中国科学技术大学科教融合学院优秀导师奖(2023)。任所学位会委员、中国复合材料学会智能复合材料专业委员会委员、Adv. Fiber Mater.青年编委等。
邸江涛研究员围绕智能仿生材料开展研究工作。在仿生肌肉智能材料方面,发明了驱动、感知、反馈等功能高度集成的新型仿生肌肉纤维,实现仿生肌肉纤维的接触与非接触感知以及驱动状态的无回滞反馈,有助推动人机交互的发展。进一步利用离子插层溶胀驱动实现了仿生肌肉纤维的无热效应、大行程、快速、稳定循环驱动;提出了离子插层驱动新方法,实现了仿生肌肉纤维的无能耗驱动态锚定和步进驱动,解决了仿生肌肉纤维驱动控制精度低的难题;在储能器件方面,提出了附加MnO2/Mn2+循环、三维电极、容式穿透沉积等策略,实现了具备高功率、高能量以及高效循环稳定的Zn-MnO2电池的制备。在Science Advances, Advanced Materials, ACS Nano, Advanced Functional Materials, Materials Horizons, Small等期刊上发表论文90余篇。申请专利48项(已授权25项)。承担了国家自然科学基金委项目(青年、面上)、科技部国家重点研发计划等项目。
研究方向/Research direction
1. 智能交互材料与器件;
2. 碳基功能复合材料;
3. 高导电纳米材料。
论文专著/The monograph
部分论文
1. Ren, Ming; Dong, Lizhong; Wang, Xiaobo; Li, Yuxin; Zhao, Yueran; Cui, Bo; Yang, Guang; Li, Wei; Yuan, Xiaojie; Zhou, Tao; Xu, Panpan; Wang, Xiaona; Di, Jiangtao*; Li, Qingwen*, Dual-Ion Co-Regulation System Enabling High-Performance Electrochemical Artificial Yarn Muscles with Energy-Free Catch States, Nano-Micro Letters 2023, 15 (1), 162, 10.1007/s40820-023-01133-2.
2. Cui, Bo; Ren, Ming; Dong, Lizhong; Wang, Yulian; He, Jianfeng; Wei, Xulin; Zhao, Yueran; Xu, Panpan; Wang, Xiaona; Di, Jiangtao*; Li, Qingwen*, Pretension-Free and Self-Recoverable Coiled Artificial Muscle Fibers with Powerful Cyclic Work Capability, ACS Nano 2023, 10.1021/acsnano.3c03942.
3. Xia, J., Zhou, Y., Zhang, J., Lu, T., Gong, W., Zhang, D.*, Wang, X.*, Di, J.*, Triggering High Capacity and Superior Reversibility of Manganese Oxides Cathode via Magnesium Modulation for Zn//MnO2 Batteries. Small 2023, 2301906. https://doi.org/10.1002/smll.202301906.
4. Dong, Lizhong; Zhang, Wei; Ren, Ming; Li, Yuxuan; Wang, Yulian; Zhou, Yurong; Wu, Yulong; Zhang, Zhijun; Di, Jiangtao*, Moisture-Adaptive Contractile Biopolymer-Derived Fibers for Wound Healing Promotion, Small 2023, 2300589.
5. Zhou, Y., Xia, J., Di, J.*, Sun, Z., Zhao, L., Li, L., Wu, Y., Dong, L., Wang, X.*, Li, Q.*, Ultrahigh-Rate Zn Stripping and Plating by Capacitive Charge Carriers Enrichment Boosting Zn-Based Energy Storage. Adv. Energy Mater. 2023, 2203165. https://doi.org/10.1002/aenm.202203165.
6. Dong, L.; Ren, M.; Wang, Y.; Wang, G.; Zhang, S.; Wei, X.; He, J.; Cui, B.; Zhao, Y.; Xu, P.; Wang, X.; Di, J.*; Li, Q.*, Artificial neuromuscular fibers by multilayered coaxial integration with dynamic adaption. Science Advances 2022, 8 (46), eabq7703.
7. Ren, M.; Xu, P.; Zhou, Y.; Wang, Y.; Dong, L.; Zhou, T.; Chang, J.; He, J.; Wei, X.; Wu, Y.; Wang, X.; Chen, W.; Di, J.*; Li, Q.*, Stepwise Artificial Yarn Muscles with Energy-Free Catch States Driven by Aluminum-Ion Insertion. ACS Nano 2022, 16 (10), 15850-15861.
8. Qiao, J.#; Wu, Y.#; Zhu, C.; Dong, L.; Wu, K.; Wang, Y.; Yang, W.; Li, M.; Di, J.*; Li, Q.*, High-performance carbon nanotube/polyaniline artificial yarn muscles working in biocompatible environments. Nano Research 2022.
9. Wang, Y.; Zhao, Y.; Ren, M.; Zhou, Y.; Dong, L.; Wei, X.; He, J.; Cui, B.; Wang, X.; Xu, P.; Di, J.*; Li, Q.*, Artificial muscle fascicles integrated with high-performance actuation properties and energy-storage function. Nano Energy 2022, 102, 107609.
10. He, J.; Ren, M.; Dong, L.; Wang, Y.; Wei, X.; Cui, B.; Wu, Y.; Zhao, Y.; Di, J.*; Li, Q.*, High-Temperature-Tolerant Artificial Muscles Using Poly(p-phenylene benzobisoxazole) Composite Yarns. Advanced Fiber Materials 2022 4, 1256.