博士生导师 硕士生导师
学历:博士研究生毕业
学位:工学博士学位
办公地点:西南交通大学九里校区3号楼
所在单位:材料科学与工程学院
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封面论文
第一或通讯作者论文
[54] Zihan Wang, Shenglong Wang, Boling Lan, Yue Sun, Longchao Huang, Yong Ao, Xuelan Li, Long Jin, Weiqing Yang and Weili Deng*. Piezotronic sensor for bimodal monitoring of Achilles tendon behavior. Nano-Micro Letters, 2025, 17, 241. (IF:31.6)
[53] Tingting Zhou, Shenglong Wang, Yong Ao, Boling Lan, Yue Sun, Guo Tian, Tao Yang, Longchao Huang, Long Jin, Lihua Tang, Weiqing Yang and Weili Deng*.High-temperature-resistance flexible piezoelectric sensor via cyclized PAN/BTO nanofibers. Nano Energy, 2025, 138, 110910.(IF:16.8)
[52] Longchao Huang, Weili Deng*, Guo Tian, Yue Sun, Tao Yang, Boling Lan, Xuelan Li, Yang Liu, Tianpei Xu, Shenglong Wang, Yong Ao, Jieling Zhang, Long Jin
and Weiqing Yang*. Low electric field-driven and fast-moving relaxor ferroelectric soft robots. InfoMat, 2025, 7(6), e70015.(IF:22.7)
[51] Yang Liu, Guo Tian, Yue Sun, Shenglong Wang, Longchao Huang, Xuelan Li, Tianpei Xu, Long Jin, Yulin Zou, Weili Deng* and Weiqing Yang*. A double
-gradient all-organic dielectric polymer film achieving superior breakdown strength and energy density. Small, 2025, 21(13), 2411304.(IF:13)
[50] Yue Sun, Guo Tian, Tao Yang, Shenglong Wang, Boling Lan, Xuelan Li, Tianpei Xu, Long Jin, Weili Deng* and Weiqing Yang*. Crosslinking-modulated hydrogel piezoionic sensor for pattern security authentication in human-machine interfaces. Advanced Functional Materials, 2025, 2420187. (IF:18.5)
[49] Weili Deng, Shenglong Wang, Xiarong Ren, Tingting Zhou, Zihan Wang, Boling Lan, Tianpei Xu, Longchao Huang, Yue Sun, Yong Ao, Long Jin and Weiqing Yang*. Highly durable MXene-based pressure sensor enabled by homogeneous interfacial locking. Wearable Electronics, 2024, 1, 236-243.
[48] Xuelan Li, Yue Sun, Shenglong Wang, Guo Tian, Tao Yang, Longchao Huang, Yong Ao, Boling Lan, Jieling Zhang, Tianpei Xu, Yang Liu, Long Jin, Weiqing Yang and Weili Deng*. Body temperature-triggered adhesive ionic conductive hydrogels for bioelectrical signal monitoring. Chemical Engineering Journal, 2024, 498, 155195.(IF:13.3)
[47] Weizhe Fan1(本科生), Shenglong Wang1, Qingyang Li1(本科生), Xiarong Ren, Chengcheng Zhang, Hanyue Wang, Murong Li, Weiqing Yang and Weili Deng*. An all-in-one array of pressure sensors and sEMG electrodes for scoliosis monitoring. Small, 2024, 2404136.(IF:13)
[46] Boling Lan, Cheng Zhong, Shenglong Wang, Yong Ao, Yang Liu, Yue Sun, Tao Yang, Guo Tian, Longchao Huang, Jieling Zhang, Weili Deng* and Weiqing Yang*. A highly sensitive coaxial nanofiber mask for respiratory monitoring assisted with machine learning. Advanced Fiber Materials, 2024, 6, 1402-1412.(IF:17.2)
[45] Zihan Wang, Yue Sun, Shenglong Wang, Da Xiong, Guo Tian, Longchao Huang, Boling Lan, Long Jin, Weiqing Yang and Weili Deng*. Insight into piezoelectricity modulation mechanism of ZnO doped with Y ions. Journal of Materials Chemistry A, 2024,12, 12435-12442. (IF:10.7)
[44] Shenglong Wang1, Yelan Yao1(本科生), Weili Deng*, Xiang Chu, Tao Yang, Guo Tian, Yong Ao, Yue Sun, Boling Lan, Xiarong Ren, Xuelan Li, Tianpei Xu, Longchao Huang, Yang Liu, Jun Lu*, and Weiqing Yang*. Mass-produced skin-inspired piezoresistive sensing array with interlocking interface for object recognition. ACS Nano, 2024, 18(17), 11183-11192. (IF:15.8)
[43]Guo Tian, Weili Deng*, Tao Yang, Jieling Zhang, Tianpei Xu, Da Xiong, Boling Lan, Shenglong Wang, Yue Sun, Yong Ao, Longchao Huang, Yang Liu, Xuelan Li, Long Jin, and Weiqing Yang*. Hierarchical piezoelectric composites for noninvasive continuous cardiovascular monitoring. Advanced Materials, 2024, 36(26), 2313612. (IF:27.4)
[42]Weili Deng, Longchao Huang, Hongrui Zhang, Guo Tian, Shenglong Wang, Tao Yang, Da Xiong, Long Jin and Weiqing Yang*. Discrete ZnO p-n homojunction piezoelectric arrays for self-powered human motion monitoring. Nano Energy, 2024, 124, 109462.(IF:16.8)
[41]Xiarong Ren, Shenglong Wang, Da Xiong, Guo Tian, Boling Lan, Weiqing Yang and Weili Deng*. Heterogeneously assembled bionic piezoresistive sensor for spinal behavior monitoring, Chemical Engineering Journal, 2024, 485, 149817.(IF:13.3)
[40] Tao Yang, Weili Deng*, Guo Tian, Lin Deng, Wanghong Zeng, You Wu, Shenglong Wang, Jieling Zhang, Boling Lan, Yue Sun, Long Jin and Weiqing Yang*. Modulating piezoelectricity and mechanical strength via three-dimensional gradient structure for piezoelectric composites. Materials Horizons, 2023, 10, 5045-5052. (IF:12.2)
[39] Wanghong Zeng, Weili Deng*, Tao Yang, Shenglong Wang, Yue Sun, Jieling Zhang, Xiarong Ren, Long Jin, Lihua Tang and Weiqing Yang*. Gradient CNT/PVDF piezoelectric composite with enhanced force-electric coupling for soccer training. Nano Research, 2023, 16(8), 11312-11319.(IF:9.5)
[38] Boling Lan, Tao Yang, Guo Tian, Yong Ao, Long Jin, Da Xiong, Shenglong Wang, Hongrui Zhang, Lin Deng, Yue Sun, Jieling Zhang, Weili Deng* and Weiqing Yang*. Multichannel gradient piezoelectric transducer assisted with deep learning for broadband acoustic sensing. ACS Applied Materials & Interfaces, 2023, 15(9), 12146-12153. (IF:9.5)
[37]Guo Tian1, Liang Tang1(本科生), Jieling Zhang, Shenglong Wang, Yue Sun, Yong Ao, Tao Yang, Da Xiong, Hongrui Zhang, Boling Lan, Lin Deng, Weili Deng* and Weiqing Yang*. Ultrathin epidermal P(VDF-TrFE) piezoelectric film for wearable electronics. ACS Applied Electronic Materials, 2023, 5 (3), 1730-1737. (IF:4.3)
[36]Shenglong Wang, Weili Deng*, Tao Yang, Yong Ao, Hongrui Zhang, Guo Tian, Lin Deng, Haichao Huang, Junfeng Huang, Boling Lan and Weiqing Yang*. Bioinspired MXene-based piezoresistive sensor with two-stage enhancement for motion capture. Advanced Functional Materials, 2023, 33,2214503.(IF:18.5)
[35]Guo Tian, Weili Deng*, Tao Yang, Da Xiong, Hongrui Zhang, Boling Lan, Lin Deng, Binbin Zhang, Long Jin, Haichao Huang, Yue Sun, Shenglong Wang and Weiqing Yang*. Insight into interfacial polarization for enhancing piezoelectricity in ferroelectric nanocomposites. Small, 2023, 19, 2207947.(IF:13)
[34]Lin Deng, Weili Deng*, Tao Yang, Guo Tian, Long Jin, Hongrui Zhang, Boling Lan, Shenglong Wang, Yong Ao, Bo Wu* and Weiqing Yang. Flexible lead-free piezoelectric Ba0.94Sr0.06Sn0.09Ti0.91O3/PDMS composite for self-powered human motion monitoring. Journal of Functional Biomaterials, 2023, 14(1), 37.(IF:5)
[33] Yue Sun, Sophia Shen, Weili Deng*, Guo Tian, Da Xiong, Hongrui Zhang, Tao Yang, Shenglong Wang, Jun Chen * and Weiqing Yang*. Suppressing piezoelectric screening effect at atomic scale for enhanced piezoelectricity. Nano Energy, 2023, 105, 108024.(IF:16.8)
[32] Shenglong Wang, Weili Deng*, Tao Yang, Guo Tian, Da Xiong, Xiao Xiao, Hongrui Zhang, Yue Sun, Yong Ao, Junfeng Huang, Jun Chen* and Weiqing Yang*. Body-area sensor network featuring micropyramids for sports healthcare. Nano Research, 2023,16(1), 1330-1337.(IF:9.5)
[31] Hongrui Zhang, Guo Tian, Da Xiong, Tao Yang, Shenglong Wang, Yue Sun, Long Jin, Boling Lan, Lin Deng, Weiqing Yang and Weili Deng*. Carrier concentration-dependent interface engineering for high-performance zinc oxide piezoelectric device. Journal of Colloid and Interface Science, 2023,629, 534-540.(IF:9.4)
[30] Jiaqing Liu(本科生), Guo Tian, Weiqing Yang and Weili Deng*. Recent progress in flexible piezoelectric devices toward human-machine interactions. Soft Science, 2022, 2(4), 22.
[29] Shenglong Wang 1, Boling Lan1, Yuyu Gao, Yanting Xie, Hanyu He, Da Xiong, Guo Tian, Tao Yang, Junfeng Huang, Yong Ao, Yue Sun, Weiqing Yang and Weili Deng*. Versatile MXene integrated assembly for piezoresistive micro-force sensing. VIEW, 2022, 3(5), 20220031. (IF:9.7)
[28] Boling Lan1, Xiao Xiao1, Aiden Di Carlo, Weili Deng*, Tao Yang, Long Jin, Guo Tian, Yong Ao, Weiqing Yang* and Jun Chen*. Topological nanofibers enhanced piezoelectric membranes for soft bioelectronics. Advanced Functional Materials, 2022, 32(49), 2207393.(IF:18.5)
[27] Hongrui Zhang, Guo Tian, Da Xiong, Tao Yang, Shen Zhong, Long Jin, Boling Lan, Lin Deng, Shenglong Wang, Yue Sun, Weiqing Yang and Weili Deng*. Understanding the enhancement mechanism of ZnO nanorod-based piezoelectric devices through surface engineering. ACS Applied Materials & Interfaces, 2022,14(25),29061-29069.(IF:8.3)
[26]Weili Deng1, Yihao Zhou1, Alberto Libanori, Guorui Chen, Weiqing Yang* and Jun Chen*. Piezoelectric nanogenerators for personalized healthcare. Chemical Society Reviews, 2022, 51, 3380-3435.(IF:40.4)
[25]Guo Tian1, Weili Deng1, Da Xiong1, Tao Yang, Binbin Zhang, Xiarong Ren, Boling Lan, Shen Zhong, Long Jin, Hongrui Zhang, Lin Deng and Weiqing Yang*. Dielectric micro-capacitance for enhancing piezoelectricity via aligning MXene sheets in composites. Cell Reports Physical Science, 2022, 3,100814.(IF:7.9)
[24]Da Xiong, Weili Deng*, Guo Tian, Binbin Zhang, Shen Zhong, Yanting Xie, Tao Yang, Haibo Zhao and Weiqing Yang*. Controllable in-situ-oxidization of 3D-networked Ti3C2Tx-TiO2 photodetectors for large-area flexible optical imaging. Nano Energy, 2022, 93,106889.(IF:16.8)
[23] Shen Zhong, Da Xiong, Binbin Zhang, Xiao Yang, Tao Yang, Guo Tian, Hongrui Zhang, Weiqing Yang and Weili Deng*. Structurally unraveling the photocarrier behavior of Cu2O/ZnO heterojunction photodetector. ACS Photonics, 2022, 9, 1, 268-274.(IF:6.5)
[22]Weili Deng1, Alberto Libanori1, Xiao Xiao, Jun Fang, Xun Zhao, Yihao Zhou, Guorui Chen, Song Li and Jun Chen*. Computational investigation of ultrasound induced electricity generation via a triboelectric nanogenerator. Nano Energy, 2022, 91,106656.(IF:16.8)
[21]Ming Zhu1, Tao Yang1, Liting Wang, Mengyuan Xiong, Wenjun He, Yaowei Chen, Weili Deng* and Xiaoyan Li*. Superstretchable electrode based on hierarchical assembly of triblock copolymer fiber membrane. Chemical Engineering Journal, 2022, 430, 132911.(IF:13.3)
[20] Tao Yang, Weili Deng*, Xiang Chu, Xiao Wang, Yeting Hu, Xi Fan, Jia Song, Yuyu Gao, Binbin Zhang, Guo Tian, Da Xiong, Shen Zhong, Lihua Tang, Yonghe Hu* and Weiqing Yang*. Hierarchically microstructure-bioinspired flexible piezoresistive bioelectronics. ACS Nano, 2021, 15(7),11555-11563. (IF:15.8)
[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.(IF:15.8)
[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. (IF:7.9)
[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. (IF:9.6)
[11]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. (IF:16.8)
[10]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. (IF:18.5)
[9]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. (IF:16.8)
[8]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.(IF:16.8)
[7]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. (IF:16.8)
[6]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.(IF:5.8)
[5] 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. (IF:8.3)
[4] 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.
[3] 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.
[2] 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.
[1] 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.
专利
[10] 邓维礼;杨维清;杨涛;邓林;钟珅;熊达;靳龙. 一种基于仿生多级结构复合柔性压阻传感器及其制备方法
[9] 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
[8] 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
[7] 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
[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
[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
[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
[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
[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
[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
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