解兆谦 - 大连理工大学

个人简介

教育经历 2006.92013.4 大连理工大学工程力学博士 2002.92006.7 大连理工大学工程力学学士工作经历 2020.2至今大连理工大学运载工程与力学学部教授 2019.42020.2 香港城市大学高级研究员 2016.42019.3 美国西北大学博士后 2013.122014.3 清华大学博士后 2013.42013.11 香港理工大学助理研究员

研究领域

研究工作主要聚焦于力学与生命健康前沿交叉领域，面向可延展柔性器件在生物医学应用中的关键科学问题，发展微器件柔性化、一体化、集成化的新型力学设计及理论。

近期论文

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[1]. Reeder J#, Xie Z#, Yang Q#, Seo M#, Yan Y, Deng Y, Jinkins K, Krishnan S, Liu C, McKay S, Patnaude E, Johnson A, Zhao Z, Kim M, Xu Y, Huang I, Avila R, Felicelli C, Ray E, Guo X, Ray W, Huang Y, MacEwan M, Rogers JA*. “Soft, bioresorbable coolers for reversible conduction block of peripheral nerves,” Science, 377(6601): 109-115, 2022. [2]. Liu Y#, Yiu C#, Song Z#, Huang Y#, Yao K, Wong T, Zhou J, Zhao L, Huang X, Nejad S, Wu M, Li D, He J, Guo X, Yu J, Feng X, Xie Z*, Yu X*, “Electronic skin as wireless human-machine interfaces for robotic VR,” Science advances, 8(2): eabl6700, 2022. [3]. Chen J#, Huang W#*, Zheng D*, Xie Z*, Zhuang X, Zhao D, Chen Y, Su N, Chen H, Pankow R, Gao Z, Yu J, Guo X, Cheng Y, Strzalka J, Yu X*, Marks T*, Facchetti A*, “Highly stretchable organic electrochemical transistors with strain-resistant performance,” Nature Materials, 27(5): 564-571, 2022. [4]. Liu Y#, Huang X#, Zhou J#, Yiu C#, Song Z#, Huang W, Nejad S, Li H, Wong T, Yao K, Zhao L, Yoo W, Park W, Li J, Huang Y, Lam H, Song E, Guo X, Wang Y, Dai Z*, Chang L*, Jung W*, Li W*, Xie Z*, Yu X*, “Stretchable Sweat-Activated Battery in Skin-Integrated Electronics for Continuous Wireless Sweat Monitoring,” Advanced Science, 2104635, 2022. [5]. Yang Y#, Wu M#, Vazquez-Guardado A#, Wegener A, Grajales-Reyes J, Deng Y, Wang T, Avila R, Moreno J, Minkowicz S, Dumronprechachan V, Lee J, Zhang S, Legaria A, Ma Y, Mehta S, Franklin D, Hartman L, Bai W, Han M, Zhao H, Lu W, Yu Y, Sheng X, Banks A, Yu X, Donaldson Z, Gereau R, Good C, Xie Z*, Huang Y*, Kozorovitskiy Y*, Rogers JA*, “Wireless multilateral devices for optogenetic studies of individual and social behaviors,” Nature Neuroscience, 24: 1035-1045, 2021. [6]. Song E#, Xie Z#, Bai W#, Luan H#, Ji B, Ning X, Xia Y, Baek J, Lee Y, Avila R, Chen H, Kim J, Madhvapathy S, Yao K, Li D, Zhou J, Han M, Won S, Zhang X, Myers D, Mei Y, Guo X, Xu S, Chang J*, Yu X*, Huang Y*, Rogers JA*, “Miniaturized electromechanical devices for the characterization of the biomechanics of deep tissue,” Nature Biomedical Engineering, 5: 759-771, 2021. [7]. Kim B#, Li K#, Kim J#, Park Y#, Jang H, Wang X, Xie Z, Won S, Jang W, Lee K, Chung T, Jung Y, Heo S, Lee Y, Kim J, Cai T, Kim Y, Prasopsukh P, Yu Y, Yu X, Luan H, Song H, Zhu F, Zhao Y, Chen L, Han S, Kim J, Oh S, Lee H, Lee C, Huang Y*, Chamorro L*, Zhang Y*, Rogers JA*, “Three-dimensional electronic microfliers with designs inspired by wind-dispersed seeds,” Nature, 597(7877): 503-510, 2021. [8]. He J#, Xie Z#, Yao K, Li D, Liu Y, Gao Z, Lu W, Chang L, Yu X*, “Trampoline inspired stretchable triboelectric nanogenerators as tactile sensors for epidermal electronics,” Nano Energy, 81: 105590, 2021. [9]. Lee K#, Ni X#, Lee JY#, Arafa H, Pe D, Xu S, Irie M, Avila R, Lee JH, Kim DH, Chung H, Olabisi O, Getaneh S, Chung E, Hill M, Bell J, Jang H, Liu C, Park JB, Kim J, Kim SB, Mehta S, Pharr M, Tzavelis A, Reeder JT, Huang I, Deng Y, Xie Z*, Davies CR*, Huang Y*, Rogers JA*, “Mechano-acoustic sensing of physiological processes and body motions via a soft wireless device placed at the suprasternal notch,” Nature Biomedical Engineering, 4: 148-158, 2020. (Cover feature article) [10]. Xie Z, Avila R, Huang Y, Rogers JA*, “Flexible and stretchable antennas for biointegrated electronics,” Advanced Materials, 32(15): 1902767, 2020. [11]. Koo J#, Kim S#, Choi Y#, Xie Z#, Bandodkar A, Khalifeh J, Yan Y, Kim H, Pezhouh M, Doty K, Lee G, Chen Y, Lee S, D’Andrea D, Jung K, Lee K, Li K, Jo S, Wang H, Kim J, Kim J, Choi S, Jang W, Oh Y, Park I, Kwak S, Park J, Hong D, Feng X, Lee C, Banks A, Lea C, Lee H, Huang Y, Franz C, Ray W, MacEwan M*, Kang S*, Rogers JA*, “Wirelessly controlled, bioresorbable drug delivery device with active valves that exploit electrochemically triggered crevice corrosion,” Science Advances, 6(35): eabb1093, 2020. [12]. Yao K#, Liu Yi#, Li D, He J, Li J, Lam R, Xie Z*, Wang L*, Yu X*, “Mechanics designs-performance relationships in epidermal triboelectric nanogenerators,” Nano Energy, 76: 105017, 2020. [13]. Liu Y, Zhao L, Avila R, Yiu C, Wong T, Chan Y, Yao K, Li D, Zhang Y*, Li W*, Xie Z*, Yu X*, “Epidermal electronics for respiration monitoring via thermo-sensitive measuring,” Materials Today Physics, 13: 100199, 2020. [14]. Liu Y, Zheng H, Zhao L, Liu S, Yao K, Li D, Yiu C, Gao S, Avila R, Chirarattananon P, Chang L*, Wang Z*, Huang X*, Xie Z*, Yang Z*, Yu X*, “Electronic skin from high-throughput fabrication of intrinsically stretchable lead zirconate titanate elastomer,” Research, 2020: 1085417, 2020. [15]. Yao K, Yao J, Hai Z, Li D, Xie Z*, Yu X*, “Stretchable self-powered epidermal electronics from piezoelectric rubber for tactile sensing,” Acta Physica Sinica, 69: 178701, 2020. [16]. Yu X#, Xie Z#, Yu Y#, Lee J#, Ruban J, Ning X, Akhtar A, Ji Bowen, Sun R, Cao J, Huo Q, Zhong Y, Lee C, Kim S, Zhang C, Xue Y, Chempakasseril A, Tian P, Lu W, Jeong J, Yu Y, Comman J, Tan C, Kim B, Lee K, Feng Xue, Huang Y*, Rogers JA*, “Skin-integrated wireless haptic interfaces for virtual and augmented reality,” Nature, 575(7783): 473-479, 2019. [17]. Chung H#, Kim B#, Lee J#, Lee J#, Xie Z#, Ibler E, Lee K, Banks A, Jeong J, Kim J, Ogle C, Grande D, Yu Y, Jang, Assem P, Ryu D, Kwak J, Namkoong M, Park J, Lee Y, Kim D, Ryu A, Jeong J, You K, Ji B, Liu Z, Huo Q, Feng X, Deng Y, Xu Y, Jang K, Kim J, Zhang Y, Ghaffari R, Rand C, Schau M, Hamvas A, Weese-Mayer D, Huang Y, Lee S, Lee C, Shanbhag N, Paller A*, Xu S*, and Rogers JA*, “Binodal, wireless epidermal electronic systems with in-sensor analytics for neonatal intensive care,” Science, 363(6430): eaau0780, 2019. [18]. Guo Q#, Koo J#, Xie Z#, Avila R, Yu X, Ning X, Zhang H, Liang X, Song A, Huang Y, Mei Y, Rogers JA*, “A bioresorbable magnetically coupled system for low-frequency wireless power transfer,” Advanced Functional Materials, 29(46): 1905451, 2019. [19]. Liu Y#, Zhao L#, Wang L#, Zheng H, Li D, Avila R, Lai K, Wang Z, Xie Z*, Zi Y*, Yu X*, “Skin-integrated graphene embedded lead Zirconate Titanate rubber for energy harvesting and mechanical sensing,” Advanced Materials Technologies, 4(12): 1900744, 2019. [20]. Xie Z*, Ji B, Huo Q, “Mechanics design of stretchable near field communication antenna with serpentine wires,” Journal of Applied Mechanics-Transactions of the ASME, 85(4): 045001, 2018. [21]. Gutruf P, Krishnamurthi V, Vázquez-Guardado A, Xie Z, Banks A, Su C, Xu Y, Haney C, Waters E, Kandela I, Krishnan S, Ray T, Leshock J, Huang Y, Chanda D, Rogers JA*, “Fully implantable optoelectronic systems for battery-free, multimodal operation in neuroscience research,” Nature Electronics, 1(12): 652-660, 2018. (Cover feature article) [22]. Kim B#, Lee J#, Won S#, Xie Z#, Chang J, Yu Y, Cho Y, Jang H, Jeong J, Lee Y, Ryu A, Kim D, Lee K, Lee J, Liu F, Wang X, Huo Q, Min S, Wu D, Ji B, Banks A, Kim J, Oh N, Jin H, Han S, Kang D, Lee C, Song Y, Zhang Y, Huang Y, Jang K*, Rogers JA*, “Three-dimensional silicon electronic systems fabricated by compressive buckling process,” ACS Nano, 12(5): 4164–4171, 2018.