吴朝兴 - 福州大学 - 物理与信息工程学院

个人简介

中共党员，福建晋江人，福州大学物理与信息工程学院、中国福建光电信息科学与技术创新实验室，教授、博士生导师，福建省“闽江学者”特聘教授。在纳米LED （nLED）、类神经智能电子器件、主动式智能感知器件、环境微能量收集与系统自供电等领域取得一系列创新成果。获得中国授权发明专利15件，韩国授权发明专利4件，作为第一作者/通讯作者在 Nature Communications 、Advanced Materials、ACS Nano (4篇)、Nano Energy (9篇，其中4篇为封面文章) 和 Applied Physics Letters (4 篇) 等顶级期刊以及其他期刊发表论文共32篇。研究生招生专业博士研究生：物理电子学、信息光电技术硕士研究生：物理电子学、信息光电技术、集成电路工程、微电子学与固体电子学欢迎硕博研究生加入我们团队！欢迎对科学探索有兴趣的本科生加入我们团队，利用课余时间开展科研训练！研究概述本课题组的研究内容涵盖纳米复合材料及其在新型光电子器件的应用，具体包括纳米LED、类神经智能电子器件、主动式智能感知器件、环境微能量收集与系统自供电等领域 Honor & award 1.福建省科学技术奖三等奖 2.韩国国家研究开发优秀成果奖 3.第十一届福建省自然科学优秀学术论文一等奖 4.福建省优秀博士论文 5.福建省三好生 6.福州大学优秀毕业论文 7.“福州大学2015届优秀博士毕业生”荣誉称号 8.2013年度卢嘉锡优秀研究生奖 9.博士研究生国家奖学金 10.福州大学研究生“十佳学术之星” 11.宝钢优秀学生奖 12.福州大学三好生 13.宝钢优秀学生奖 Patent 1 、一种石墨烯复合柔性透明电极及其制备方法，中国，ZL201410165017.2 2、一种叠层结构的三端有源器件，中国， ZL201310135175.9 3 、基于聚合物/金属离子复合体系的阻变存储器及制备方法，中国， ZL201110292265.X 4、基于石墨烯/氧化锌纳米线复合材料的发射阴极及其制备，中国 ZL201110067559.2 5、一种基于石墨烯的表面传导电子发射源，中国，ZL201210329143.8 6 、一种图形化的石墨烯场发射阴极及其制备方法，中国， ZL201110292565.8 7 、一种基于阻变材料的三端全控型开关元件及其制备方法，中国，ZL201110140230.4 8、一种利用感应加热制备石墨烯的方法，中国，ZL201310712919.9 9、一种基于3D打印泡沫金属制备立体石墨烯的方法，中国，ZL201410237601.4 10、一种基于石墨烯的柔性光电器件封装方法，中国，ZL201310716400.8 11、基于氧化物纳米结构的表面传导电子发射源及其制作方法，中国，ZL201110167432.8 12、一种多功能集成的有机阻变存储装置及其制备方法，中国，ZL201210064637.8 13、一种由碳纳米管制备石墨烯量子点的方法，中国，ZL201210525033.9 14 、一种基于石墨烯量子点掺杂的有机阻变存储器及制备方法，中国，ZL201310000243.0 15 、基于石墨烯量子点的三体系有机光伏器件及其制备方法，中国，ZL201210467633.4 16 、柔性忆阻装置的制作方法，韩国，10-1809361 17 、一种具有条件反射功能的神经装置及其驱动方法，韩国，10-1874187 18 、基于纳米复合材料的电子源的制备方法，韩国，10-1791326 19、电子纺织品的制造方法及其在光电器件和可穿戴发电机的应用，韩国，10-1928706 20、一种基于纸张的摩擦纳米发电机及其制作方法，韩国，10-1952533

研究领域

开展纳米复合材料电学性能研究及其在新型光电子器件的应用应用。

近期论文

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1. Wu, Chaoxing; Kim, Tae Whan; Guo, Tailiang; Li, Fushan; Lee, Dea Uk; Yang, J Joshua. Mimicking classical conditioning based on a single flexible memristor. Advanced Materials 2017, 29: 1602890. 2. Wu, Chaoxing; Kim, Tae Whan; Chok, Hwan Young; Strukov Dmitri B; Yang, J. Joshua. Flexible three-dimensional artificial synapse networks with correlated learning and trainable memory capability. Nature Communications 2017, 8: 752. 3. Wu, Chaoxing; Park, Jae Hyeon; Koo, Bonmin; Chen, Xiangyu; Wang, Zhong Lin; Kim, Tae Whan. Capsule Triboelectric Nanogenerators: Toward Optional 3D Integration for High Output and Efficient Energy Harvesting from Broadband-Amplitude Vibrations. ACS nano 2018, 12: 9947-9957. 4. Wu, Chaoxing; Kim, Tae Whan; Park, Jae Hyeon; An, Haoqun; Shao, Jiajia; Chen, Xiangyu; Wang, Zhong Lin. Enhanced Triboelectric Nanogenerators Based on MoS2 Monolayer Nanocomposites Acting as Electron-Acceptor Layers. ACS nano 2017, 11: 8356-8363. 5. Wu, Chaoxing; Kim, Tae Whan; Li, Fushan; Guo, Tailiang. Wearable electricity generators fabricated utilizing transparent electronic textiles based on polyester/Ag nanowires/graphene core–shell nanocomposites. ACS nano 2016, 10: 6449-6457. 6. Wu, Chaoxing; Kim, Tae Whan; Park, Jae Hyeon; Koo, Bonmin; Sung, Sihyun; Shao, Jiajia; Zhang, Chi; Wang, Zhong Lin. Self-Powered Tactile Sensor with Learning and Memory. ACS nano 2020, 14: 1390-1398. 7. Wu, Chaoxing; Kim, Tae Whan; Guo, Tailiang; Li, Fushan. Wearable ultra-lightweight solar textiles based on transparent electronic fabrics. Nano Energy 2017, 32: 367-373. 8. Wu, Chaoxing; Kim, Tae Whan; Choi, Hwan Young. Reduced graphene-oxide acting as electron-trapping sites in the friction layer for giant triboelectric enhancement. Nano Energy 2017, 32: 542-550. (Front cover) 9. Wu, Chaoxing; Kim, Tae Whan; Sung, Sihyun; Park, Jae Hyeon; Li, Fushan. Ultrasoft and cuttable paper-based triboelectric nanogenerators for mechanical energy harvesting. Nano Energy 2018, 44: 279-287. 10. Wu, Chaoxing; Park, Jae Hyeon; Sung, Sihyun; Koo, Bonmin; Lee, Yong Hun; Kim Tae Whan. Integrable card-type triboelectric nanogenerators assembled by using less problematic, readily available materials. Nano Energy 2018, 51: 383-3907. 11. Xu, Zhongwei; Wu, Chaoxing; Li, Fushan; Chen, Wei; Guo, Tailiang; Kim, Tae Whan. Triboelectric electronic-skin based on graphene quantum dots for application in self-powered, smart, artificial fingers. Nano Energy 2018, 49: 274–282. (Front cover) 12.Park, Jae Hyeon; Wu, Chaoxing; Sung, Sihyun; Kim, Tae Whan. Ingenious use of natural triboelectrification on the human body for versatile applications in walking energy harvesting and body action monitoring. Nano Energy 2019, 57: 872-878. 13. Li, Dianlun; Wu, Chaoxing*; Ruan, Lu; Wang, Jiaxin; Qiu, Zhirong; Wang, Kun; Liu, Ye; Zhang, Yufei; Guo, Tailiang; Lin, Jintang*; Kim, Tae Whan*. Electron-transfer mechanisms for confirmation of contact-electrification in ZnO/polyimide-based triboelectric nanogenerators. Nano Energy 2020, 75: 104818. 14. Liu, Ye; Wang, Kun; Wu, Chaoxing; Park, Jae Hyeon; Lin, Zhixian; Zhang, Yongai; Zhou, Xiongtu; Guo, Tailiang; Kim, Tae Whan. Triboelectric-nanogenerator-inspired light-emitting diode-in-capacitors for flexible operation in high-voltage and wireless drive modes. Nano Energy 2020, 78: 105281. 15. Xu, Zhongwei; Li, Fushan; Wu, Chaoxing*; Ma, Fumin; Zheng, Yueting; Yang, Kaiyu; Chen, Wei; Hu, Hailong; Guo, Tailiang; Kim Tae Whan, Ultrathin electronic synapse having high temporal/spatial uniformity and an Al2O3/graphene quantum dots/Al2O3 sandwichstructure for neuromorphic computing. NPG Asia Materials 2019, 11:18. 16. Wu, Chaoxing; Zhang, Yongai; Zhou, Xiongtu; Li, Dianlun; Park, Jae Hyeon; An, Haoqun; Sung, Sihyun; Lin, Jintang; Guo, Tailiang; Li, Fushan; Kim, Tae Whan. Binary Electronic Synapses for Integrating Digital and Neuromorphic Computation in a Single Physical Platform. ACS applied materials & interfaces 2020, 12: 17130-17138. 17. Shao, Jiajia; Jiang, Tao; Tang, Wei; Xu, Liang; Kim, Tae Whan; Wu, Chaoxing; Chen, Xiangyu; Chen, Baodong; Xiao, Tianxiao; Bai, Yu; Wang, Zhong Lin. Studying about Applied Force and the Output Performance of Sliding-Mode Triboelectric Nanogenerators. Nano Energy 2018, 48: 292-300. 18. Ma, Fumin; Zhu, Yangbin; Xu, Zhongwei; Liu, Yang; Zheng, Xiaojing; Ju, Songman; Li, Qianqian; Ni, Ziquan; Hu, Hailong; Chai, Yang; Wu, Chaoxing; Kim, Tae Whan; Li, Fushan. Optoelectronic Perovskite Synapses for Neuromorphic Computing. Advanced Functional Materials 2020, 19. Liu, Yang; Li, Fushan; Qiu, Lichun; Yang, Kaiyu; Li, Qianqian; Zheng, Xin; Hu, Hailong; Guo, Tailiang; Wu, Chaoxing; Kim, Tae Whan. Fluorescent Microarrays of in Situ Crystallized Perovskite Nanocomposites Fabricated for Patterned Applications by Using Inkjet Printing. ACS nano 2019, 13: 2042-2049. 20. Wu, Chaoxing; Li, Fushan; Zhang, Yongai; Guo, Tailiang. Improving the field emission of graphene by depositing zinc oxide nanorods on its surface. Carbon 2012, 50: 3622-3626. 21. Choi, Hwan Young; Wu, Chaoxing; Bok, Chang Han; Kim; Tae Whan. Organic electronic synapses with pinched hystereses based on graphene quantum-dot nanocomposites. NPG Asia Materials 2017, 9: e413. 22. Li, Fushan; Kou, Lijie; Chen, Wei; Wu, Chaoxing; Guo, Tailiang. Enhancing the short-circuit current and power conversion efficiency of polymer solar cells with graphene quantum dots derived from double-walled carbon nanotubes. NPG Asia Materials 2013, 5: e60. 23. Kim, Do Hyeong; Wu, Chaoxing; Park, Dong Hyun; Kim, Woo Kyum; Seo, Hae Woon; Kim, Sang-Wook; Kim, Tae Whan. Flexible Memristive Devices Based on InP/ZnSe/ZnS Core-Multishell Quantum Dot Nanocomposites. ACS applied materials & interfaces 2018, 10: 14843-14849. 24. Zhou, Xiongtu; Lin, Tihang; Liu, Yuhui; Wu, Chaoxing; Zeng, Xiangyao; Jiang, Dong; Zhang, Yong-ai; Guo, Tailiang. Structural, optical, and improved field-emission properties of tetrapod-shaped Sn-doped ZnO nanostructures synthesized via thermal evaporation. ACS applied materials & interfaces 2013, 5: 10067-10073. 25. Liu, Yang; Li, Fushan; Perumal Veeramalai, Chandrasekar; Chen, Wei; Guo, Tailiang; Wu, Chaoxing; Kim, Tae Whan. Inkjet-Printed Photodetector Arrays Based on Hybrid Perovskite CH3NH3PbI3 Microwires. ACS Applied Materials & Interfaces 2017, 9: 11662-11668. 26. Wu, Chaoxing; Kim, Tae Whan; Guo, Tailiang; Li, Fushan. Unique visible-light-assisted field emission of tetrapod-shaped ZnO/reduced graphene-oxide core/coating nanocomposites. Scientific Reports 2016, 6: 38613. 27. Wu, Chaoxing; Li, Fushan; Chen, Wei; Veeramalai, Chandrasekar Perumal; Ooi, Poh Choon; Guo, Tailiang. Electromagnetic induction heating for single crystal graphene growth: morphology control by rapid heating and quenching. Scientific Reports 2015, 5: 9034. 28. Wang, Kun; Liu, Ye; Wu, Chaoxing*; Li, Dianlun; Lv, Shanhong; Zhang, Yongai; Zhou, Xiongtu*; Guo, Tailiang*. Electroluminescence from μLED without external charge injection. Scientific Reports 2020, 10: 8059. 29. Wu, Chaoxing; Li, Fushan; Zhang, Yongai; Guo, Tailiang; Chen, Ting. Highly reproducible memory effect of organic multilevel resistive-switch device utilizing graphene oxide sheets/polyimide hybrid nanocomposite. Applied Physics Letters 2011, 99: 42108. 30. Wu, Chaoxing; Li, Fushan; Zhang, Yongai; Guo, Tailiang. Recoverable electrical transition in a single graphene sheet for application in nonvolatile memories. Applied Physics Letters 2012, 100: 42105. 31. Wu, Chaoxing; Li, Fushan; Guo, Tailiang. Efficient tristable resistive memory based on single layer graphene/insulating polymer multi-stacking layer. Applied Physics Letters 2014, 104: 183105. 32. Wu, Chaoxing; Li, Fushan; Wu, Wei; Chen, Wei; Guo, Tailiang. Liquid-phase exfoliation of chemical vapor deposition-grown single layer graphene and its application in solution-processed transparent electrodes for flexible organic light-emitting devices. Applied Physics Letters 2014, 105: 243509. 33. Wu, Chaoxing; Li, Fushan; Guo, Tailiang; Kim, Tae Whan. Controlling memory effects of three-layer structured hybrid bistable devices based on graphene sheets sandwiched between two laminated polymer layers. Organic Electronics 2012, 13: 178-183. 34. Wu, Chaoxing; Li, Fushan; Zhang, Yongai; Guo, Tailiang; Qu, Bo; Chen, Zhijian. Field emission arrays fabricated utilizing conjugated ZnO quantum dot/carbon nanotube hybrid nanocomposite. Applied Surface Science 2011, 257: 4539-4542. 35. Wu, Chaoxing; Li, Fushan; Zhang, Yongai; Guo, Tailiang. A surface-conducted field emission device with suspended graphene cathodes. Applied Surface Science 2013, 273: 432-436. 36. Sung, Sihyun; Wu, Chaoxing; Jung, Hyun Soo; Kim Tae Whan. Highly-stable write-once-read-many-times switching behaviors of 1D–1R memristive devices based on graphene quantum dot nanocomposites. Scientific Reports 2018, 8: 12081. 37. Lee, Jeong Heon; Wu, Chaoxing; Sung, Sihyun; An, Haoqun; Kim, Tae Whan. Highly flexible and stable resistive switching devices based on WS 2 nanosheets: poly (methylmethacrylate) nanocomposites. Scientific Reports 2019, 9: 19316. 38. Ma, Zehao; Wu, Chaoxing; Lee, Dea Uk; Li, Fushan; Kim, Tae Whan. Carrier transport and memory mechanisms of multilevel resistive memory devices with an intermediate state based on double-stacked organic/inorganic nanocomposites. Organic Electronics 2016, 28: 20-24. 39. Bok, Chang Han; Wu, Chaoxing; Kim, Tae Whan. Operating mechanisms of highly-reproducible write-once-read-many-times memory devices based on graphene quantum dot: poly (methyl silsesquioxane) nanocomposites. Applied Physics Letters 2017, 110: 13301. 40. Zhang, YA; Wu, CX; Lin, JY; Lin, ZX; Guo, TL. An improved planar-gate triode with CNTs field emitters by electrophoretic deposition. Applied Surface Science 2011, 257: 3259-3264. 41. Kim, Woo Kyum; Wu, Chaoxing; Kim, Tae Whan. Effect of a PEDOT:PSS modified layer on the electrical characteristics of flexible memristive devices based on graphene oxide:polyvinylpyrrolidone nanocomposites. Applied Surface Science 2018, 444: 65-70. 42. Kim, Woo Kyum; Wu, Chaoxing; Lee, Dea Uk; Kim, Hyoun Woo; Kim, Tae Whan. Enhancements of the memory margin and the stability of an organic bistable device due to a graphene oxide: mica nanocomposite sandwiched between two polymer (9-vinylcarbazole) buffer layers. Applied Surface Science 2018, 429: 231. 43. Sung, Sihyun; Park, Jae Hyeon; Wu, Chaoxing; Kim, Tae Whan. Biosynaptic devices based on chicken egg albumen: graphene quantum dot nanocomposites. Scientific Reports 2020, 10: 1255. 44. Bok, Chang Han; Woo, Sung Jun; Wu, Chaoxing; Park, Jae Hyeon; Kim, Tae Whan. Flexible bio-memristive devices based on chicken egg albumen:Au@SiO2 core-shell nanoparticle nanocomposites. Scientific Reports 2017, 7: 12033. 45. Koo, Bon Min; Sung, Sihyun; Wu, Chaoxing; Song, Jin-Won; Kim, Tae Whan. Flexible organic synaptic device based on poly (methyl methacrylate):CdSe/CdZnS quantum-dot nanocomposites. Scientific Reports 2019, 9: 9755. 46. Chen, Wei; Li, Fushan; Wu, Chaoxing; Guo, Tailiang. Optical properties of fluorescent zigzag graphene quantum dots derived from multi-walled carbon nanotubes. Applied Physics Letters 2014, 104: 63109. 47. An, Haoqun; Kim, Woo Kyum; Wu, Chaoxing; Kim, Tae Whan. Highly-stable memristive devices based on poly(methylmethacrylate): CsPbCl3 perovskite quantum dot hybrid nanocomposites. Organic Electronics 2018, 56: 41-45. 48. Choi, Myoung Kyun; Kim, Woo Kyum; Sung, Sihyun; Wu, Chaoxing; Kim, Hyoun Woo; Kim Tae Whan. Flexible memristive devices based on polyimide_mica nanosheet nanocomposites with an embedded PEDOT:PSS layer. Scientific Reports 2018, 8: 12275. 49. An, Haoqun; Lee, Yong Hun; Lee, Jeong Heon; Wu, Chaoxing; Koo, Bon Min; Kim, Tae Whan. Highly Stable and Flexible Memristive Devices Based on Polyvinylpyrrolidone: WS2 Quantum Dots. Scientific Reports 2020, 10: 5793. 50. Wen, Liang; Li, Fushan; Xie, Jiangxing; Wu, Chaoxing; Zheng, Yong; Chen, Dongling; Xu, Sheng; Guo, Tailiang; Qu, Bo; Chen, Zhijian. Electroplex emission at PVK/Bphen interface for application in white organic light-emitting diodes. Journal of luminescence 2011, 131: 2252-2254. 51. Chen, Guixiong; Weng, Yalian; Sun, Fan; Zhou, Xiongtu; Wu, Chaoxing; Yan, Qun; Guo, Tailiang; Zhang, Yongai. Low-temperature atomic layer deposition of Al2O3/alucone nanolaminates for OLED encapsulation. RSC Advances 2019, 9:20884–20891. 52. Kim, Do Hyeong; Kim, Woo Kyum; Woo, Sung Jun; Wu, Chaoxing; Kim, Tae Whan. Highly-reproducible nonvolatile memristive devices based on polyvinylpyrrolidone: Graphene quantum-dot nanocomposites. Organic Electronics 2017, 51: 156-161. 53. Chen, Leifeng; Yu, Hua; Zhong, Jiasong; Wu, Chaoxing; Hu, Liqin; Zhang, Tian. Effectively improved field emission properties of multiwalled carbon nanotubes/graphenes composite field emitter by covering on the Si pyramidal structure. IEEE Transactions on Electron Devices 2015, 62: 4305-4312. 54. Ma, Fumin; Xu, Zhongwei; Liu, Yang; Zheng, Yueting; Chen, Wei; Hu, Hailong; Guo, Tailiang; Li, Fushan; Wu, Chaoxing; Kim, Tae Whan. Highly-reliable Electronic synapse Based on Au@ Al2O3 Core-shell Nanoparticles for Neuromorphic Applications. IEEE Electron Device Letters 2019, 40: 1610-1613. 55. Li, Hao-Hong; Li, Yi; Gong, An-Wen; Wu, Chao-Xing; Zhu, Jia; Dong, Hai-Jun; Li, Fu-Shan; Chen, Zhi-Rong. Structure and Electrical Bistability of a New Inorganic/Organic Hybird Based on Copper Iodide Polymer and Ethyl Viologen: A Synergic Combination of Experimental and Theoretical Study. Science of Advanced Materials 2015, 7: 1793-1799. 56. Li, Dianlun; Ruan, Lu; Sun; Jie ; Wu, Chaoxing; Yan, Ziwen; Lin,Jintang; Qun Yan. Facile growth of aluminum oxide thin film by chemical liquid deposition and its application in devices. Nanotechnology Reviews 2020, 9: 876-885. 57. Li, Fushan; Lin, Zhixiao; Zhang, Beibei; Zhang, Yongzhi; Wu, Chaoxing; Guo, Tailiang. Fabrication of flexible conductive graphene/Ag/Al-doped zinc oxide multilayer films for application in flexible organic light-emitting diodes. Organic Electronics 2013, 14: 2139-2143. 58. Guo, Fan; Ye, Yun; Yang, Zunxian; Hong, Chunyan; Hu, Liqin; Wu, Chaoxing; Guo, Tailiang. The in situ preparation of novel α-Fe2O3 nanorods/CNTs composites and their greatly enhanced field emission properties. Applied Surface Science 2013, 270: 621-626. 59. Chen, Leifeng; He, Hong; Yu, Hua; Cao, Yiqi; Lei, Da; Menggen, QiQiGe; Wu, Chaoxing; Hu, Liqin. Electron field emission characteristics of graphene/carbon nanotubes hybrid field emitter. Journal of Alloys and Compounds 2014, 610: 659-664. 60. Wu, Chaoxing; Li, Fushan; Zhang, Yongai; Guo, Tailiang. Effectively improved field emission for graphene film by mechanical surface modification. Thin Solid Films 2013, 544: 399-402. 61. Wu, Chaoxing; Li, Fushan; Zhang, Yongai; Guo, Tailiang. Field emission from vertical graphene sheets formed by screen-printing technique. Vacuum 2013, 94: 48-52.（Front Cover） 62. Wu, Chaoxing; Li, Fushan; Zhang, Yongai; Wang, Lingjie; Guo, Tailiang. Formation and field emission of patterned zinc oxide-adhering graphene cathodes. Vacuum 2013, 89: 57-61. 63. Wu, Chaoxing; Li, Fushan; Guo, Tailiang. Formation and carrier transport properties of single-layer graphene/poly (methyl methacrylate) nanocomposite for resistive memory application. Vacuum 2014, 101: 246-249. 64. Wu, Chaoxing; Li, Fushan; Guo, Tailiang. Resistive Switching Memory Based on Three-Dimensionally Confined Ag Quantum Dots Embedded in Ultra Thin Polyimide Layers. Journal of nanoscience and nanotechnology. 2013, 13: 1173-1176. 65. Wu, Chaoxing; Li, Fushan; Zhang, Yongai; Wang, Lingjie; Guo, Tailiang. Enhanced field emission performance of tetrapod-liked zinc oxide nanoneedles by coating with graphene oxide sheets. Current Nanoscience 2012, 8: 23-25. 66. Wang, Lingjie; Wu, Chaoxing; Ye, Yun; Yang, Zunxian; Guo, Tailiang. The field emission properties of backlight unit based on two kinds of SnO2 nanostructures. Current Nanoscience 2012, 8: 29-32. 67. Li, Fushan; Lin, Zhixiao; Zhang, Beibei; Wu, Chaoxing; Hong, Chunyan; Guo, Tailiang. Electrical and optical properties of flexible conductive carbon nanotube/Ag/Al-doped zinc oxide multilayer coatings. Thin Solid Films 2012, 525: 93-96. 68. Li, Fushan; Zhang, Yongzhi; Wu, Chaoxing; Lin, Zhixiao; Zhang, Beibei; Guo, Tailiang. Improving efficiency of organic light-emitting diodes fabricated utilizing AZO/Ag/AZO multilayer electrode. Vacuum 2012, 86: 1895-1897. 69. Liu, Yang; Li, Fushan; Chen, Zhixin; Guo, Tailiang; Wu, Chaoxing; Kim, Tae Whan. Resistive switching memory based on organic/inorganic hybrid perovskite materials. Vacuum 2016, 130: 109-112. 70. Wu, Wei; Li, Fushan; Nie, Chen; Wu, Jiaqi; Chen, Wei; Wu, Chaoxing; Guo, Tailiang. Improved performance of flexible white hybrid light emitting diodes by adjusting quantum dots distribution in polymer matrix. Vacuum 2015, 111: 42739. 71. Wu, Chaoxing; Li, Fushan; Guo, Tailiang; Qu, Bo; Chen, Zhijian; Gong, Qihuang. Efficient nonvolatile rewritable memories based on three-dimensionally confined Au quantum dots embedded in ultrathin polyimide layers. Japanese Journal of Applied Physics 2011, 50: 30204. 72. Wu, Chaoxing; Li, Fushan; Guo, Tailiang; Kim, Tae Whan. Carrier transport in volatile memory device with SnO2 quantum dots embedded in a polyimide layer. Japanese Journal of Applied Physics 2011, 50: 95003. 73. Wang, LJ; Wu, CX; Lin, JY; Ye, Y; Yang, ZX; Guo, TL. Effect of nanostructured morphologies of SnO2 on field emission properties. The European Physical Journal-Applied Physics 2012, 58. 74. Zhang, YA; Lin, JY; Wu, CX; Li, FS; Guo, TL. Stable field emission from planar-gate electron source with MWNTs by electrophoretic deposition. Solid-State Electronics 2012, 67: 42896. 75. Zhang, Beibei; Li, Fushan; Lin, Zhixiao; Wu, Chaoxing; Guo, Tailiang; Liu, Wenbin; Su, Yang; Du, Jinhong. Flexible white organic light-emitting diodes based on single-walled carbon nanotube: poly (3,4-ethylenedioxythiophene)/poly (styrene sulfonate) transparent conducting film. 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