封面论文  

                                                          

第一或通讯作者论文

[19]   Weili Deng¹, Yihao Zhou¹, Xun Zhao¹, Songlin Zhang, Yongjiu Zou, Jing Xu, Min-Hsin Yeh,* Hengyu Guo,* and Jun Chen*. Ternary electrification layered architecture for high-performance triboelectric nanogenerators. ACS Nano, 2020, 14(7), 9050-9058.

   

[18]   Yihao Zhou¹, Weili Deng¹, Jing Xu and Jun Chen*. Engineering materials on the nanoscale for triboelectric nanogenerators. Cell Reports Physical Science, 2020，1(8), 100142.     

[17]   Guo Tian, Da Xiong, Yuhan Su, Tao Yang, Yuyu Gao, Cheng Yan,Wen Deng, Long Jin, Haitao Zhang, Weili Deng*, and Weiqing Yang*. Understanding the potential screening effect through the discretely structured ZnO nanorods piezo array. Nano Letters, 2020, 20(6), 4270-4277.                      

     

[16]   Tao Yang, Hong Pan, Guo Tian, Da Xiong, Yuyu Gao, Cheng Yan, Xiang Chu, Lei Zhang, Weili Deng*, and Weiqing Yang*. Hierarchically structured PVDF/ZnO core-shell nanofibers for self-powered physiological monitoring electronics. Nano Energy, 2020, 72, 104706. (封面文章)                                 

[15]   Yuyu Gao¹, Cheng Yan¹, Haichao Huang, Tao Yang, Guo Tian, Da Xiong, Ningjun Chen, Xiang Chu, Shen Zhong, Weili Deng*, Yong Fang* and Weiqing Yang*. Microchannel-confined MXene based flexible piezoresistive multifunctional micro-force sensor. Advanced Functional Materials, 2020, 30,1909603.

[14]   Cheng Yan¹, Yuyu Gao¹, Shenlong Zhao, Songlin Zhang, Yihao Zhou, Weili Deng*, Ziwei Li, Gang Jiang, Long Jin, Guo Tian, Tao Yang, Xiang Chu, Da Xiong, Zixing Wang, Yongzhong Li, Weiqing Yang* and Jun Chen*. A linear-to-rotary hybrid nanogenerator for high-performance wearable biomechanical energy harvesting. Nano Energy, 2020, 67,10423. (Hot paper, ESI highly cited)                         

[13]   Weili Deng¹, Tao Yang¹, Long Jin, Cheng Yan, Haichao Huang, Xiang Chu, Zixing Wang, Da Xiong, Guo Tian, Yuyu Gao, Haitao Zhang and Weiqing Yang*. Cowpea-structured PVDF/ZnO nanofibers based flexible self-powered piezoelectric bending motion sensor towards remote control of gestures. Nano Energy, 2019, 55, 516. (ESI highly cited）

  

[12]   Guo Tian, Weili Deng*, Yuyu Gao, Da Xiong, Cheng Yan, Xuebing He, Tao Yang, Long Jin, Xiang Chu, Haitao Zhang, Wei Yan and Weiqing Yang*. Rich lamellar crystal baklava-structured PZT/PVDF piezoelectric sensor toward individual table tennis training. Nano Energy, 2019, 59, 574.                            

[11]   Da Xiong, Weili Deng*, Guo Tian, Yuyu Gao, Xiang Chu, Cheng Yan, Long Jin, Yuhan Su, Wei Yan and Weiqing Yang*. A piezo-phototronic enhanced serrate-structured ZnO-based heterojunction photodetector for optical communication. Nanoscale, 2019, 11, 3021.                               

[10]  Cheng Yan, Weili Deng*, Long Jin, Tao Yang, Zixing Wang, Xiang Chu, Hai Su, Jun Chen* and Weiqing Yang*. Epidermis inspired ultrathin 3D cellular sensors array for self-powered biomedical monitoring. ACS Applied Materials & Interfaces, 2018，10(48),41070-41075. (封面文章)                  

             

[9]  Weili Deng, Long Jin, Yueqi Chen, Wenjun Chu, Binbin Zhang, Huan Sun, Da Xiong, Zekai Lv, Minhao Zhu and Weiqing Yang*. An enhanced low-frequency vibration ZnO nanorods-based tuning fork piezoelectric nanogenerator. Nanoscale, 2018, 10(2), 843.

[8]  Weili Deng, Binbin Zhang, Long Jin, Yueqi Chen, Wenjun Chu, Haitao Zhang, Minhao Zhu and Weiqing Yang*. Enhanced performance of ZnO microballoon arrays for triboelectric nanogenerator. Nanotechnology, 2017, 28(13), 135401. 

[7]  Weili Deng, Long Jin, Binbin Zhang, Yueqi Chen, Lin Mao, Haitao Zhang and Weiqing Yang*. A flexible field-limited ordered ZnO nanorods-based self-powered tactile sensor array for electronic skin. Nanoscale, 2016, 8(36), 16302.

[6]  Weili Deng, Xinjie Huang, Wenjun Chu, Yueqi Chen, Lin Mao, Qi Tang and Weiqing Yang*. Microstructure-based interfacial tuning mechanism of capacitive pressure sensors for electronic skin. Journal of Sensors, 2016, 8,12504.

[5] 邓维礼, 楮文俊, 黄欣杰. 用于细胞培养的便携式电刺激器设计与实现. 传感器与微系统, 2017, 36(5):113-115.

[4] 邓维礼, 陈怀, 张明, 甘吉松, 黄凯. 基于LabVIEW的焊接机器人的监测与报警系统. 测控技术, 2016, 35(6):105-107.

[3] 邓维礼, 肖南, 永远. 基于超声技术轮轨接触状态监测的数值模拟. 西南交通大学学报, 2014, 49(6):1073-1077.

[2] 邓维礼, 永远. 超声波在轮轨材料中传播的数值模拟. 西南交通大学学报, 2012, 47(5):836-841.

[1] 邓维礼, 秦岚, 刘俊, 许斌. 基于Multisim的准静态电荷放大器仿真分析. 国外电子测量技术, 2009, 28(4):24-26.

   专利

       [11]    邓维礼;杨维清;杨涛;闫成;靳龙;熊达;赵凡漪. 一种柔性压电纳米纤维膜及其制备方法和应用（发明专利）

       [10]    邓维礼;谢超鸣;鲁雄;王科锋. 高通量电刺激诱导细胞分化及药物控释的实验装置及方法（发明专利）

       [9]      邓维礼;杨维清;张海涛;靳龙;张彬彬;毛林;苏海. 一种基于氧化锌微球阵列修饰的摩擦发电机（发明专利）

       [8]      杨维清;邓维礼;熊达;田果;高育育;闫成;靳龙;杨涛. 氧化锌纳米棒/氧化亚铜锯齿状异质结及其制备方法以及应用（发明专利）

       [7]      杨维清;田果;邓维礼;高育育;熊达;闫成;杨涛;靳龙. 复合压电材料、其制备方法、压力传感膜、球拍、辅助练球装置及检测击球质量的方法（发明专利）

       [6]      邓维礼;李炎翰;娄亮;徐铭坤;杨维清. 一种汽车尾气净化装置（实用新型）

       [5]      邓维礼;吕泽楷;杨维清;靳龙; 胡成见; 张伟; 蒲犇; 唐安表. 自供能头盔 （实用新型）

       [4]      邓维礼;杨维清;何其沛; 魏居垚; 刘禹清; 胡成见; 陈楚珺. 基于振动效应的能量采集装置（实用新型）

       [3]      邓维礼;胡成见;杨维清; 何其沛; 魏居垚; 刘禹清. 一种复合型能量采集器（实用新型）

       [2]     邓维礼;谢超鸣;鲁雄; 王科峰. 一种用于细胞培养的高通量电刺激仪（实用新型）

       [1]     邓维礼;杨维清;翟福琪; 杨涛; 赵凡漪; 朱婷; 蔡万源; 李兆峰; 熊达; 田果. 一种柔性力敏传感器及其制备方法、阵列器件和应用 （发明专利）

     科研项目

9、国家自然科学基金青年基金项目，阵列型ZnO/P(VDF-TrFE)柔性压电材料的层次化构建及触觉传感特性研究，主持

8、中央高校基本科研业务费科技创新项目，柔性电子皮肤用1-3型压电复合材料的制备及压电响应机制的研究，主持

7、企事业单位委托项目，基底表面进行图形化结构的微纳加工，主持

6、企事业单位委托项目，多种基底表面进行图形化结构制备，主持

5、军委科技委项目，基于基于磁悬浮复合纳米发电机的自供电智能战士头盔，主研

4、国家自然科学基金面上项目，二维碳纳米材料高压原位诱导压电聚合物自组装晶体结构及其智能化研究，参与

3、国家自然科学基金面上项目，声表面波-分子键裂型生物传感器，参与

2、四川省科技厅项目，基于纳米发电机的轨道交通能量回收利用及其机理研究，参与

1、企事业单位委托项目，星形精密轧机及永磁节能传动的优化技术研究，参与