个人简历:
徐文涛,南开大学杰出教授。获得国家杰出青年科学基金,国家级人才,天津市海河英才行动计划领军人才,天津市杰出青年科学基金等人才项目资助;主持重点研发计划(973)等项目课题;获得天津市自然科学一等奖(排名1)等奖励。曾任韩国浦项工科大学和首尔国立大学研究副教授,在美国四院院士伊利诺大学香槟分校John Rogers教授研究组和美国两院院士、中科院外籍院士斯坦福大学鲍哲南教授研究组访问学习和合作研究。
徐文涛教授近十年以通讯/第一作者共发表论文70余篇,包括Science、Science Advances、Matter、Nature Communications(3篇)、Advanced Materials (6篇)和ACS Nano(2篇)、Advanced Functional Materials(4篇)、Nano Energy (5篇)等国际权威期刊。2项工作入选Science、Nature、Nature Nanotechnology 的研究亮点,多项工作入选Nature Communications、Advanced Materials等杂志的封面。申请专利40余项,其中12项已获授权,参编著作2部。并致力于以下几个方面的研究:
1)在国际上首次提出并研获柔性人造传入神经,重现了人类皮肤的触觉功能,赋予人造皮肤感知能力。该工作被 Nature 评为研究亮点,称这一开创性研究有望实现人机兼容新途径:可应用于人工假肢,使其直观感知外界刺激,为截肢者和神经瘫痪者恢复肢体功能提供有效帮助;有望应用于软体机器人,使其具有类似于人的信息识别与记忆功能,从而在极端工作环境中替代人。成果具有开创性意义,对未来人造皮肤与人工假肢触觉传入、兼容性人机接口实现以及神经系统疾病治疗等均有重要的参考意义。
2)首次提出并证实不同神经递质切换的模拟机制及人造运动神经可切换控制原理,率先成功研制出可对人造肌肉不同运动方向切换控制的国际首条人造传出神经,这种完全模拟神经信息传输原理的控制体系与传统控制体系相比,具有更好的生物神经逻辑兼容性,为类人操控系统、人机交互和人造假肢提供了原理上的参考;系统开展关于人造突触功耗降低和对电压响应灵敏度提高两大方面的研究,提出并证实利用电解质和纳米功能材料结合体系中高效离子扩散可实现突触器件功耗降低和电压响应灵敏度提升,研制出迄今为止,功耗最低、对电压响应灵敏度最高的两端人造突触。
3)深入研究先进低维纳米材料的可控制备方案与构效关系,制备出一系列光电性能强、量子效率高、机械柔性韧性好等高性能低维纳米材料,设计基于低维纳米材料的神经形态器件结构,深入研究构效关系,建立了低维神经电子材料体系,为人造神经体系提供材料设计原理和工艺支撑。
教育背景:
2001.9-2005.7 北京师范大学 本科
2005.9-2007.6 (韩)大邱大学 硕士
2008.3-2012.2 (韩) 浦项工科大学 电子材料专业 博士 (导师: Prof. Shi-Woo Rhee 韩国国家支持实验室,芯片系统中心主任)
2011.11-2012.2 (美) 伊利诺伊大学香槟分校 访问学生 (导师: Prof. John A Rogers 美国国家科学院、美国国家工程院、美国国家医学院、美国艺术与科学学院四院院士)
工作经历:
2012.2-2013.8 (韩) 浦项工科大学 打印纳米电子实验室 博士后研究员 (导师: Prof. Tae-Woo Lee 韩国科学技术院院士)
2013.8-2016.8 (韩) 浦项工科大学 研究助/副教授
2016.5-2016.11 (美) 斯坦福大学 访问学者(导师: Prof. Zhenan Bao 美国国家工程院院士、美国艺术与科学院院士、中国科学院外籍院士)
2016.10-2017.9 (韩) 首尔国立大学 研究副教授
2017.9 ~ 南开大学 教授、博士生导师
科研项目:
1、 国家科学技术部,国家重点研发计划“纳米前沿”专项,“石墨炔电化学能源存储与转换器件前沿”,2023.05-2028.04,300万。(在研,主持)
2、 国家自然科学基金委,国家杰出青年科学基金,“神经形态电子材料与器件”,2022.01-2026.12,400万。(在研,主持)
3、 国家科学技术部,国家重点研发计划政府间国际创新合作(中国和韩国政府间联合研究项目),“多感知柔性人工神经构建与功能探究”,2022.06-2025.05,100万。(在研,主持)
4、 国家级人才项目,2018.02-2021.02,300万。(结题,主持)
5、 天津市科技局,杰出青年基金项目,“基于数码可控打印纳米线的神经形态电子器件”,2019.10-2023.09,100万。(在研,主持)
6、 天津市教育委员会,天津市“海河英才行动计划”领军人才,2018.06——至今,50万。(在研,主持)
7、 天津市科学技术委员会,面上项目,“新型功能性纳米材料在神经仿生电子器件方面的研究“,2018.04-2021.03,10万。(结题,主持)
8、 南开大学百名青年学科带头人培养计划,2017.09-2021.09,50万。(结题,主持)
9、 广东省科技厅,省部级项目,“类脑神经器件”,2019.01-2021.12,80万。(结题,参加)
10、 中国电子科技集团公司第五十八研究所,横向项目,“高精度金属再布线打印技术开发”,2020.06-2020.08,15万。(结题,主持)
l 撰写论文:
1、 Science, 2018, 360 (6392), 998-1003. Yeongin Kim†, Alex Chortos†, Wentao Xu*†, Yuxin Liu, Jin Young Oh, Donghee Son, Jiheong Kang, Amir M. Foudeh, Chenxin Zhu, Yeongjun Lee, Simiao Niu, Jia Liu, Raphael Pfattner, Zhenan Bao*, Tae-Woo Lee*, A bioinspired flexible organic artificial afferent nerve (通讯作者,共同一作). (影响因子= 63.741)
2、 Nature Communications, 2023, 14(1), 1344. Chengpeng Jiang, Jiaqi Liu, Yao Ni, Shangda Qu, Lu Liu, Yue Li, Lu Yang, Wentao Xu*, Mammalian brain-inspired neuromorphic motion-cognition nerve achieves cross-modal perceptual enhancement. (杂志封面) (影响因子= 17.694)
3、 Nature Communications, 2022, 13(1), 7427. Jiaqi Liu†, Jiangdong Gong†, Huanhuan Wei, Yameng Li, HaixiaWu, Chengpeng Jiang, Yuelong Li*, Wentao Xu*, A bioinspired flexible neuromuscular systembased thermal-annealing-free perovskitewith passivation. (影响因子= 17.694)
4、 Nature Communications, 2021, 12(1), 1068. Huanhuan Wei††, Rongchao Shi††, Lin Sun††, Jiangdong Gong, Chao Liu, Zhipeng Xu, Yao Ni, Jialiang Xu*, Wentao Xu*, Mimicking efferent nerves using a graphdiyne-based artificial synapse with multiple ion diffusion dynamics. (影响因子= 17.694)
5、 Science Advances, 2016, 2(6), e1501326. Wentao Xu, Sung-Yong Min, Hyunsang Hwang and Tae-Woo Lee, Organic core-sheath nanowire artificial synapses with femtojoule energy consumption. (影响因子=14.957)
6、 Advanced Materials, 2021, 33(10), 2007350. Shuo Zhang†, Kexin Guo†, Lin Sun†, Yao Ni, Lu Liu, Wenlong Xu, Lu Yang, Wentao Xu*, Selective release of different neurotransmitters emulated by a p-i-n junction synaptic transistor for environment-responsive action control. (影响因子= 32.086)
7、 Advanced Materials, 2021, 33(26), 2101981. Wentao Xu†, Lihua Wang†, David ChangMo Yang, Amir Hajibabaei, Yeongjun Lee, Cheolmin Park, Tae-Woo Lee,* and Kwang S. Kim*, Supra-binary polarization in a ferroelectric nanowire. (影响因子= 32.086)
8、 Advanced Materials, 2016, 28(3), 527-532. Wentao Xu, Himchan Cho, Young-Hoon Kim, Tae-Woo Lee, Organometal halide perovskite artificial synapses. (杂志内封面) (影响因子= 32.086)
9、 Advanced Materials, 2016, 28(28), 5916-5922. Wentao Xu, Yeongjun Lee, Sung-Yong Min, Cheolmin Park and Tae-Woo Lee, Simple, inexpensive, and rapid approach to fabricate cross-shaped memristors using an inorganic-nanowire-digital-alignment technique and a one-step reduction process. (杂志内封面) (影响因子= 32.086)
10、 Advanced Materials, 2015, 27(9), 1619-1623. Wentao Xu, Lihua Wang, Yiwen Liu, Simil Thomas, Hong-Kyu Seo, Kwang-Ik Kim, Kwang S. Kim, and Tae-Woo Lee, Controllable n-type doping on CVD-grown single- and double-layer graphene mixture. (影响因子=32.086)
11、 Advanced Materials, 2014, 26(21), 3459-3464. Wentao Xu, Hong-Kyu Seo, Sung-Yong Min, Himchan Cho, Tae-Seok Lim, Yeongjun Lee, and Tae-Woo Lee, Rapid fabrication of designable large-scale aligned graphene Nanoribbons by Electro-hydrodynamic nanowire lithography. (影响因子= 32.086)
12、 Matter, 2022, 5(5), 1578-1589. Jiangdong Gong, Huanhuan Wei, Jiaqi Liu, Lin Sun, Zhipeng Xu, Hao Huang, Wentao Xu*, An artificial visual nerve for mimicking pupil reflex. (影响因子= 19.967)
13、 Research, 2022, 9851843. Lin Sun, Yi Du, Haiyang Yu, Huanhuan Wei, Wenlong Xu, Wentao Xu*, An artificial reflex arc that perceives afferent visual and tactile information and controls efferent muscular actions. (影响因子= 11.036)
14、 npj 2D Materials and Applications, 2021, 5(1), 23. MingXue Ma†, Yao Ni†, Zirong Chi, Wanqing Meng, Haiyang Yu, Jiangdong Gong, Huanhuan Wei, Hong Han, Xinran Wang, Wentao Xu*,Multiplexed neurochemical transmission emulated using a dual-excitatory synaptic transistor. (影响因子= 10.516)
15、 Advanced Functional Materials, 2022, 2210119. Lu Liu†, Yao Ni†, Jiaqi Liu†, Yihang Wang, Chengpeng Jiang, Wentao Xu*, An artificial autonomic nervous system that implements heart and pupil as controlled by artificial sympathetic and parasympathetic nerves. (影响因子= 19.924)
16、 Advanced Functional Materials, 2021, 31(1), 2007232. Huanhuan Wei, Haiyang Yu, Jiangdong Gong, MingXue Ma, Hong Han, Yao Ni, Shuo Zhang, Wentao Xu*, Redox mxene artificial synapse with bidirectional plasticity and hypersensitive responsibility. (影响因子= 19.924)
17、 Advanced Functional Materials, 2021, 31(27), 2101917. Shuo Zhang, Kexin Guo, Hong Han, Haiyang Yu, Huanhuan Wei, Jiangdong Gong, Wentao Xu*,Multiplexed neurotransmission emulated by a p–n cross nanowire synaptic transistor for satiety, depression, and drug withdrawal. (影响因子= 19.924)
18、 Advanced Functional Materials, 2020, 30(46), 2005413. Jiangdong Gong†, Haiyang Yu†, Xin Zhou†, Huanhuan Wei, MingXue Ma, Hong Han, Shuo Zhang, Yao Ni, Yuelong Li*, Wentao Xu*, Lateral artificial synapses on hybrid perovskite platelets with modulated Recent Process of Flexible Transistor-Structured Memory neuroplasticity. (影响因子= 19.924)
19、 ACS Nano, 2022, 16(2), 2282-2291. Lu Liu, Wenlong Xu, Yao Ni, Zhipeng Xu, Binbin Cui, Jiaqi Liu, Huanhuan Wei, Wentao Xu*, Stretchable neuromorphic transistor that combines multi-sensing and information processing for epidermal gesture recognition. (影响因子= 18.027)
20、 ACS Nano, 2022, 16, 12, 20294-20304. Yao Ni†, Lu Liu†, Jiaqi Liu†, Wentao Xu*, A high-strength neuromuscular system that implements reflexes as controlled by a multiquadrant artificial efferent nerve. (影响因子= 18.027)
21、 Nano-Micro Letters, 2023, (Accepted). Lixiu Zhang et al., Wentao Xu*, Lu Zhu*, Wenhua Zhang*, Guichuan Xing*, Feng Gao*, and Liming Ding*, Advances in the application of perovskite materials. (影响因子= 23.655)
22、 Advanced Science, 2022, 9(24), 2106124. Chengpeng Jiang, Jiaqi Liu, Lu Yang, Jiangdong Gong, Huanhuan Wei, Wentao Xu*, A flexible artificial sensory nerve enabled by nanoparticle-assembled synaptic devices for neuromorphic tactile recognition. (影响因子= 17.521)
23、 Advanced Science, 2021, 2102036. Yao. Ni†, Jiulong. Feng†, Jiaqi. Liu†, Hang. Yu, Huanhuan. Wei, Yi. Du, Lu. Liu, Lin. Sun, Jianlin. Zhou, Wentao Xu*, An artificial nerve capable of UV-perception, NIR-Vis switchable plasticity modulation, and motion state monitoring. (影响因子= 17.521)
24、 Nano Energy, 2022, 104,107898. Yao Ni, Hong Han, Jiaqi Liu, Yongsuk Choi, Lu Liu, Zhipeng Xu, Lu Yang, Chengpeng Jiang, Wei Gao, Wentao Xu*, A fibrous neuromorphic device for multi-level nerve pathways implementing knee jerk reflex and cognitive activities. (影响因子= 19.069)
25、 Nano Energy, 2021, 81, 105648. Huanhuan Wei†, Yao Ni†, Lin Sun†, Haiyang Yu, Jiangdong Gong, Yi Du, MingXue Ma, Hong Han, Wentao Xu*,Flexible electro-optical neuromorphic transistors with tunable synaptic plasticity and nociceptive behavior. (影响因子= 19.069)
26、 Nano Energy, 2021, 86, 106038. Yao Ni†, MingXue Ma†, Huanhuan Wei, Jiangdong, Gong, Hong Han, Lu Liu, Zhipeng Xu, Wentao Xu*, Multiplexed neurotransmiss ion emulated for emotion control. (影响因子= 19.069)
27、 Nano Energy, 2018, 48, 575–581. Wentao Xu, Thanh Luan Nguyen, Young-Tae Kim, Christoph Wolf, Raphael Pfattner, Jeffrey Lopezd, Byeong-Gyu Chae, Sung-Il Kim, Moo Yeol Lee, Eul-Yong Shin, Yong-Young Noh, Joon Hak Oh, Hyunsang Hwang, Chan-Gyung Park, Han Young Woo, Tae-Woo Lee, Ultrasensitive artificial synapse based on conjugated polyelectrolyte. (影响因子= 19.069)
28、 Nano Energy, 2019, 58, 437-446. Tae-Sik Kim†, Yeongjun Lee†, Wentao Xu†, Miseong Kim, Yeon Hoo Kim, Sung Yong Min, Tae Hoon Kim, Ho Won Jang, Tae-Woo Lee, Direct-printed nanoscale metal-oxide-wire electronics. (影响因子= 19.069)
29、 Nano Letters, 2023, 23(1), 8-16. Lu Yang†, Zixian Wang†, Song Zhang, Yue Li, Chengpeng Jiang, Lin Sun, Wentao Xu*, Neuromorphic gustatory system with salt-taste perception, information processing, and excessive-intake warning capabilities. (影响因子= 12.262)
30、 SmartMat, 2023, 4(2), e1154. Yao Ni, Lu Yang, Jiulong Feng, Jiaqi Liu, Sun Lin, Wentao Xu*, Flexible optoelectronic neural transistors with broadband spectrum sensing and instant electrical processing for multimodal neuromorphic computing. (IF= pending)
31、 Materials Horizons, 2016, 3(3), 186-207. Wentao Xu, Tae-Woo Lee, Recent progress in fabrication techniques of graphene nanoribbons. (影响因子=15.717)
32、 Nanoscale Horizons, 2020, 5(9), 1324-1331. Hong Han, Feng Ge, MingXue Ma, Haiyang Yu, Huanhuan Wei, Xue Zhao, Hongbing Yao, Jiangdong Gong, Longzhen Qiu*, Wentao Xu*,Mixed receptors of AMPA and NMDA emulated using a ‘Polka Dot’-structured two-dimensional conjugated polymer-based artificial synapse. (影响因子= 11.684)
33、 Small, 2021, 17(9), 2000041. Haiyang Yu, Huanhuan Wei, Jiangdong Gong, Hong Han, MingXue Ma, Yongfei Wang, Wentao Xu*, Evolution of bio-inspired artificial synapses: materials, structures, and mechanisms. (影响因子:15.153)
34、 Small, 2021, 17(9), 1905332. Yao Ni, Yongfei Wang, Wentao Xu*, Recent process of flexible transistor-structured memory. (杂志内封面) (影响因子:15.153)
35、 Small, 2019, 15(32), 1900695. Hong Han, Haiyang Yu, Huanhuan Wei, Jiangdong Gong, Wentao Xu*, Recent progress on three-terminal artificial synapses: from device to system. (杂志内封面) (影响因子:15.153)
36、 Small, 2014, 10(10), 1999-2005. Wentao Xu, Tae-Seok Lim, Hong-Kyu Seo, Sung-Yong Min, Himchan Cho, Min-Ho Park, Young-Hoon Kim, and Tae-Woo Lee, N-doped graphene field-effect transistors with enhanced electron mobility and air-stability. (影响因子= 15.153)
37、 Materials Today Nano 2022, (17) 100167. Yao Ni#, Lu Yang#, Lu Liu, Huanhuan Wei, Zhipeng Xu, Jiaqi Liu, Hong Han, Wentao Xu*, Mimicking ion-balance-dependent synaptic plasticity in body fluid for adaptive environment-responsive artificial neuromuscular reflexes.
38、 Applied Materials Today, 2021, 25, 101223. Yao. Ni†, Shuo. Zhang†, Lin. Sun, Lu. Liu, Huanhuan. Wei, Zhipeng. Xu, Wenlong. Xu, Wentao Xu*, A low-dimensional hybrid p-i-n heterojunction neuromorphic transistor with ultra-high UV sensitivity and immediate switchable plasticity. (影响因子= 8.663)
39、 Mater. Today Phys, 2021, 18, 100329. Huanhuan Wei†, Hong Han†, Kexin Guo†, Haiyang Yu, Jiangdong Gong, MingXue Ma, Yao Ni, Jiulong Feng, Zhipeng Xu, Wentao Xu*,Artificial synapses that exploit ionic modulation for perception and integration. (影响因子= 11.021)
40、 Mater. Today Phys, 2021, 21, 100540. Jiangdong Gong, Huanhuan Wei, Yao Ni, Shuo Zhang, Yi Du, Wentao Xu, Methylammonium halide-doped perovskite artificial synapse for light-assisted environmental perception and learning. (影响因子= 11.021)
41、 Adv. Intelligent Syst, 2020, 2(3), 1900176. Hong Han, Zhipeng Xu, Kexin Guo, Yao Ni, MingXue Ma, Haiyang Yu, Huanhuan Wei, Jiangdong Gong, Shuo Zhang, Wentao Xu*,Tunable synaptic plasticity in crystallized conjugated polymer nanowire artificial synapses. (影响因子= 7.298)
42、 Sci. China Mater, 2019, 62(11), 1709–1726. Wenlong Xu, Shuo Zhang, Wentao Xu*,Recent progress on electrohydrodynamic nanowire printing. (影响因子=8.640)
43、 Mater. Chem. Front, 2021, 5(2), 775-782. Huanhuan Wei, Haiyang Yu, Jiangdong Gong, Renjie Li, Hong Han, MingXue Ma, Kexin Guo, Wentao Xu*,Conversion-type electrochemi cal artificial synapse for plastici ty modulation and dendritic application. (影响因子= 8.683)
44、 Mater. Chem. Front, 2019, 3(5), 941-947. Haiyang Yu, Jiangdong Gong, Huanhuan Wei, Wei Huang, Wentao Xu*, Mixed-halide perovskite for ultrasensitive two-terminal artificial synaptic devices. (影响因子=8.683)
45、 Nanoscale, 2021, 13(45), 19190-19199. Shuo Zhang, Lu Yang, Chengpeng Jiang, Lin Sun, Kexin Guo, Hong Han, Wentao Xu*, Digitally-aligned ZnO nanowire array based synaptic transistors with intrinsically controlled plasticity for short-term computation and longterm memory. (影响因子= 8.307)
46、 J. Ind. Eng. Chem, 2020, 88(25), 111-116. Lu Liu, Binbin Cui, Wenlong Xu, Yao Ni, Shuo Zhang, Wentao Xu*,Highly aligned indium zinc oxide nanowire-based artificial synapses with low-energy consumption. (影响因子:6.760)
47、 ACS Photonics, 2023, 10(1), 242–252. Lin Sun, Shangda Qu, Yi Du, Lu Yang,Yue Li, Zixian Wang, Wentao Xu*, Bio-inspired vision and neuromorphic image processing using printable metal oxide photonic synapses. (杂志封面) (影响因子= 7.077)
48、 Chinese Chemical Letters, 2023, (In Press). Yao Ni†, Lu Liu†, Jiulong Feng, Lu Yang, Wentao Xu*, Flexible organic artificial synapse with ultrashort-term plasticity for tunable timefrequency signal processing. (影响因子= 8.455)
49、 Chinese Chemical Letters, 2023, 34(2), 107292. Zhipeng Xu†, Yao Ni†, Hong Han, Huanhuan Wei, Lu Liu, Shuo Zhang, Hao Huang, Wentao Xu*, A hybrid ambipolar synaptic transistor emulating multiplexed neurotransmission for motivation control and experience-dependent learning. (影响因子= 8.455)
50、 J. Mater. Chem. C, 2013, 1(25), 3955-3960. Wentao Xu, Chang Guo, Shi-Woo Rhee, High performance organic field-effect transistors using cyanoethyl pullulan (CEP) high-k polymer cross-linked with trimethylolpropane triglycidyl ether (TTE) at low temperatures. (影响因子= 8.067)
51、 J. Mater. Chem. C, 2020, 8(32), 11138-11144. Shuo Zhang, Wentao Xu*, All-printed ultra-flexible organic nanowire artificial synapses. (影响因子= 8.067)
52、 J. Mater. Chem, 2012, 22(14), 6597-6602. Wentao Xu, Chang Guo, Shi-Woo Rhee,“Knitting up” the inter-dipole gaps in dielectric surfaces: an efficient route for high performance organic field-effect transistors. (影响因子= 6.626)
53、 J. Mater. Chem., 2012, 22(4), 1482-1488. Wentao Xu, Feng Wang, Shi-Woo Rhee, Quasi-ordering in spontaneously associated surface dipoles: an intrinsic interfacial factor for high-kpolymer insulated organic field-effect transistors. (影响因子= 6.626)
54、 J. Mater. Chem. 2009, 19, 5250-5257. Wentao Xu, Shi-Woo Rhee, Low-operating voltage organic field-effect transistors with high-k cross-linked cyanoethylated pullulan polymer gate dielectric. (影响因子= 6.626)
55、 J. Mater. Chem, 2011, 21(4), 998-1004. Wentao Xu, Shi-Woo Rhee, Compromise of electrical leakage and capacitance density effects: a facile route for high mobility and sharp subthreshold slope in low-voltage operable organic field-effect transistors. (影响因子= 6.626)
56、 ACS Appl. Electron. Mater, 2020, 2(2), 316-322. Huanhuan Wei, Haiyang Yu, Jiangdong Gong, Jie Zhang, Hong Han, MingXue Ma, Yao Ni, Yi Du, Shuo Zhang, Lu Liu, Wentao Xu*, Lithium ion alloying-type artificial synapses. (影响因子= 4.494)
57、 Nanotechnology, 2018, 30(1), 012001. Yihang Chen, Haiyang Yu, Jiangdong Gong, MingXue Ma, Hong Han, Huanhuan Wei, Wentao Xu*, Artificial synapses based on nanomaterials. (影响因子= 3.953)
58、 Nanotechnology, 2019, 30(20), 202002. Haiyang Yu, Yihang Chen, Huanhuan Wei, Jiangdong Gong, Wentao Xu*, High-k polymeric gate insulators for organic field-effect transistors. (影响因子= 3.953)
59、 Org. Electron, 2010, 11(6), 996-1004. Wentao Xu, Shi-Woo Rhee, Organic field-effect transistors with cross-linked high-k cyanoethylated pullulan polymer as a gate insulator. (影响因子= 3.868)
60、 Org. Electron, 2010, 11(5), 836-845. Wentao Xu, Shi-Woo Rhee, Hysteresis-free organic field-effect transistors with high dielectric strength cross-linked polyacrylate copolymer as a gate insulator. (影响因子= 3.868)
61、 Org. Electron, 2011, 12(12), 2040-2046. Wentao Xu, Shi-Woo Rhee, Low-temperature self-curable polyacrylate copolymer gate insulator for hysteresis-free organic field-effect transistors. (影响因子= 3.868)
62、 Fundamental Research, 2022, DOI: 10.1016/j.fmre.2022.03.024. Lu Yang, Yao Ni, Chengpeng Jiang, Lu Liu, Song Zhang, Jiaqi Liu, Lin Sun, Wentao Xu*, A neuromorphic device mimicking synaptic plasticity under different body fluid K+ homeostasis for artificial reflex path construction and pattern recognition. (IF= pending)
63、 RSC Advances, 2016, 6(115), 114593-114598. Xue-feng She, Jingsong Wang, Qingguo Xue, Wentao Xu*, Raw product of rare-earth ore works as a high-k gate insulator for low-voltage operable organic field-effect transistors. (影响因子= 4.036)
64、 Polymer, 2007, 748, 6286-6293. Wentao Xu* Chanhong Chung, Younghwan Kwon, Synthesis of novel block copolymers containing polyhedral oligomeric silsesquioxane (POSS) pendent groups via ring-opening metathesis polymerization (ROMP). (第一作者/通讯作者) (影响因子= 4.432)
65、 Semicond. Sci. Technol, 2020, 35(10), 104001. Jiangdong Gong, Haiyang Yu, Huanhuan Wei, Yongshen Zhen, Chunqing Yuan, MingXue Ma, Hong Han, Kexin Guo, Jialiang Xu, Wentao Xu*, An air-stable two-dimensional perovskite artificial synapse. (影响因子= 2.048)
66、 Acta Physica Sinica, 2022, 71(14), 148501. Qiang Liu, Yao Ni, Lu Liu, Lin Sun, Jiaqi Liu, Wentao Xu*, Artificial synapses based on layered multi-component metal oxides. (影响因子= 0.906)
67、 Acta Physica Sinica, 2020, 69(23), 238501. Guo Ke-Xin, Yu Hai-Yang, Han Hong, Wei Huan-Huan, Gong Jiang-Dong, Liu Lu, Huang Qian, Gao Qing-Yun, Wentao Xu**, Artificial synapse based on MoO3 nanosheets prepared by hydrothermal synthesis. (影响因子= 0.906)
68、 Neuromorphic Computing and Engineering, 2022, 2(1), 014004. Hao Huang, Lu Liu, Chengpeng Jiang, Jiangdong Gong, Yao Ni, Zhipeng Xu, Huanhuan Wei, Haiyang Yu, Wentao Xu*, Two-dimensional molybdenum disulfide artificial synapse with high sensitivity. (IF= pending)
69、 Advanced Sensor Research, 2023, 2200051. Yi Du, Lin Sun, Lu Yang, Wentao Xu*, A wearable flexible tactile sensor with textile microstructure for wirelessly recognizing human activity. (IF= pending)
70、 Frontiers in Nanotechnology, 2021, 3, 625989. Zixian Wang, Lin Sun, Yao Ni, Lu Liu, Wentao Xu*, Flexible electronics and their healthcare applications.
以共同作者身份发表的论文
71、 Science Advances, 2018, 4(11), eaat7387. Y. Lee, J. Y. Oh, W. Xu, O. Kim, T. R. Kim, J. Kang, Y. Kim, D. Son, J. B.-H. Tok, M. J. Park, Z. Bao, T.-W. Lee, Stretchable organic optoelectronic sensorimotor synapse. (影响因子= 14.957)
72、 Advanced Materials, 2016, 28(41) 9109–9116. Yeongjun Lee, Sung-Yong Min, Tae-Sik Kim, Su-Hun Jeong, Ju Yeon Won, Hobeom Kim, Wentao Xu, Jae Kyeong Jeong, and Tae-Woo Lee, Versatile metal nanowiring platform for large-scale nano- and opto-electronic devices. (影响因子= 32.086)
73、 Advanced Materials, 2014, 26, 8010. Yeongjun Lee, Tae-Sik Kim, Sung-Yong Min, Wentao Xu, Su-Hun Jung, Hong-Kyu Seo, and Tae-Woo Lee, Individually position-addressable metal-nanofiber electrodes for large-area electronics. (封面文章) (影响因子= 32.086)
74、 Angew. Chem. Int. Ed, 2016, 55(21), 6197-6201. Tae-Hee Han, Sung-Joo Kwon, Nannan Li, Hong-Kyu Seo, Wentao Xu, Kwang S. Kim, and Tae-Woo Lee, Versatile p-type chemical doping to achieve ideal flexible graphene electrodes. (影响因子= 16.823)
75、 Small, 2015, 11, 45. Sung-Yong Min, Tae-Sik Kim, Yeongjun Lee, Himchan Cho, Wentao Xu, and Tae-Woo Lee, Organic nanowire fabrication and device applications. (影响因子= 15.153)
76、 ACS Appl. Mater. Interfaces, 2018, 10 (5), pp 4874–4881. Sung-Joo Kwon, Tae-Hee Han, Young-Hoon Kim, Towfiq Ahmed, Hong-Kyu Seo, Hobeom Kim, Dong Jin Kim, Wentao Xu, Byung Hee Hong, Jian-Xin Zhu, and Tae-Woo Lee, Solution-processed n-type graphene doping for cathode in inverted polymer light-emitting diodes. (影响因子= 10.383)
77、 Adv. Opt. Mater, 2016, 4(6), 974. Himchan Cho, Su-Hun Jeong, Sung-Yong Min, Tae-Hee Han, Min-Ho Park, Young-Hoon Kim, Wentao Xu and Tae-Woo Lee, Scalable noninvasive organic fiber lithography for large-area optoelectronics. (后封面文章) (影响因子= 10.050)
78、 Adv. Electron. Mater, 2019, 29(5),1970031. S.-I. Kim, Y. Lee, M.-H. Park, G.-T. Go, Y.-H. Kim, W. Xu, H. -D. Lee, H. Kim, D.-G. Seo, W. Lee, T.-W. Lee, Dimensionality-dependent plasticity in halide perovskite artificial synapses for neuromorphic computing. (影响因子= 7.633)
79、 Sci. Rep, 2015, 5, 16710. Hong-Kyu Seo, Tae-Sik Kim, Sang-Hoon Bae, Wentao Xu, Hee Cheul Choi, Jong-Hyun Ahn, Tae-Woo Lee, Value-added synthesis of graphene: recycling industrial carbon waste into electrodes for high-performance electronic devices. (影响因子= 4.996)
80、 Macromolecular Res, 2008, 16, 155-162. Su-Dong Park, Wentao Xu, Chanhong Chung, Younghwan Kwon, Amphiphilic norbornene-based diblock copolymers containing polyhedral oligomeric silsesquioxane prepared by living ring opening metathesis polymerization. (影响因子= 2.127)
讲授课程:
本科生课程:
有机与柔性电子器件、信息显示、功能电子材料与节能器件
研究生课程:
信息前沿讲座
获奖情况:
2022 天津市自然科学一等奖(排名第一)
2021 国家杰出青年自然科学基金获得者
2019 天津市杰出青年基金获得者
2018 国家四青人才
2017 南开大学百名青年学科带头人
2011 优秀博士研究生奖
2010 国家优秀自费留学生奖
科技交流:
47、(特邀报告分论坛主席) 徐文涛,柔性人造感知运动神经:材料、器件与系统柔性电子技术与应用创新论坛,苏州, 2023.5.20-5.22。
46、(特邀报告) 徐文涛,Design and Fabrication of neuromorphic electronic devices 18th IEEE International Conference on Nano/Micro Engineered and Molecular Systems (IEEE NEMS 2023),韩国济州岛,2023.5.14-2023.5.17。
45、(特邀报告) 徐文涛,柔性人造感知运动神经,InfoSummit信息技术材料国际会议,四川成都丽景家园酒店,2023.5.12-5.14。
44、(特邀报告) 徐文涛,人造感觉与运动神经及其在医疗健康方面的应用探索,中国生命电子学年会,广东省佛山市,2023.5.9-5.12。
43、(特邀报告) 徐文涛, 基于神经形态器件的人造传入与传出神经,中国仪器仪表学会力触觉感知与交互专业委员会成立大会暨2023第二届力触觉技术及应用会议,南京金鹰尚美酒店,2023.4.21-4.22
42、(特邀报告) 徐文涛, 柔性人造感知运动神经:材料、器件与系统,第一届iEnergy峰会,线上,2023.1.13-1.15。
41、(特邀报告) 徐文涛,神经仿生电子器件,第五届“生物、有机与纳米电子学”研讨会,江苏南京·线上,2023.01.06-01.08
40、(特邀报告) Wentao Xu, Artificial synapses and sensorimotor nerves,The 2022 Flexible Magnetoelectric Functional Materials and Devices Symposium and the second Annual Conference of Lujiassi International Team, Ningbo, Zhejiang Province, 2022.12.1-12.2。
39、(特邀报告) Wentao Xu, Artificial afferent and efferent nerves based on neuromorphic devices, 2022 Cross-Straits and Hong Kong and Macao Young Scientists Intelligent Wearable Technology Innovation Forum, Hangzhou, 2022.11.2-11.7
38、(特邀报告) Wentao Xu, Artificial Sensorimotor Nerves and Synaptic Devices, 4th IEEE International Flexible Electronics Technology Conference(IFETC 2022),山东青岛,2022.8.21-8.24
37、(特邀报告) Wentao Xu, Synaptic Electronic Devices based on Multi-Dimensional Materials,第四届全国有机场效应晶体管会议暨第二届柔性印刷光电材料与器件会议(OFET-4 & ICFPOE-2),湖南长沙现代凯莱大酒店,2022.7.29-7.31;
36、(特邀报告) Wentao Xu,Artificial synapses and sensorimotor neurons, International Conference on Frontier Materials 2022,珠海国际会展中心,2022.5.27-5.31;
35、(特邀报告) 徐文涛,第二十五期南开化学青年论坛,八里台校区石先楼二楼报告厅,神经形态电子材料与器件, 2022.2.23.(分会主持);
34、(特邀报告) 徐文涛, YONSEI-CBE International Workshop Series: Nano Electronics 2022 (Virtual), Artificial Synapses and Sensorimotor Neurons, 2022.2.8.
33、(特邀报告) 徐文涛,国家自然科学基金委交叉科学部首届青年学术研讨会,北京益田影人花园酒店一层群英会厅,2021.10.9-10.11(邀请报告)
32、(特邀报告) 徐文涛,人造突触与感觉运动神经,全国柔性与印刷电子技术研讨会,苏州金鸡湖国际会议中心,2021.10.27-10.28(大会报告)
31、(特邀报告) 徐文涛,第二届柔性印刷光电材料与器件国际会议,湖南省长沙市现代凯莱大酒店,2021.9.10-12(邀请报告)
30、(特邀报告) 徐文涛,Artificial synapses and sensorimotor neurons, Materials, Devices, and Packaging Technologies for Soft Bioelectronics,线上,2021.8.18-8.19(邀请报告)
29、(特邀报告) 徐文涛,Design of Artificial Synapses and Sensorimotor Neurons,The 16th IEEE International Conference on Nano/Micro Engineered & Molecular Systems (IEEE-NEMS 2021),厦门,2021.4.25-29
28、(特邀报告) 徐文涛,突触器件与感觉/运动神经,京津冀国家技术创新中心首届光电技术创新大会,北京协同创新研究院,2021年4月17-18日;
27、(特邀报告,分会主席)徐文涛,Artificial synapses and sensorimotor nerves,第五届IEEE电子器件技术与制造(EDTM)会议2021(5th IEEE Electron Devices Technology and Manufacturing (EDTM) Conference 2021),四川省成都世纪城新国际会展中心(Chengdu Century City New International Convention and Exhibition Center),2021.4.8-11.
26、(特邀报告) 徐文涛,Design of synaptic devices using multi-dimensional materials,the Special International Symposium on Hybrid Materials and Processing (HyMaP 2020-Special), 韩国釜山(线上), 2020,11.26-11.28
25、(特邀报告) 徐文涛; International Conference on Electronic Materials Leading the Future (ICE-MLF2019) 引领未来电子材料国际会议, 韩国庆熙大学, 2019-11-14至2019-11-15.
24、(特邀报告) 徐文涛; From Device to System, Meeting of the 5th International Symposium of Flexible & Stretchable Electronics 2019(ISFSE 2019) 2019年柔性及可拉伸电子器件第五届国际研讨会, 南方科技大学, 2019-6-29至2019-6-30.
23、(大会报告) 徐文涛,中国机器人学术年会暨顶刊论坛,湖北武汉, 2018年12月8-10日。
22、(特邀报告) 徐文涛,2018新型功能材料国际会议,辽宁鞍山,邀请报告、分会主持人,2018年9月16-18日。l
21、(大会报告) 徐文涛,2018玻璃-纳米功能材料研讨会,湖北武汉,2018年6月28-30日。
20、(特邀报告) Wentao Xu, Synaptic Electronic Devices and Their Applications. 4th International Symposium of Flexible & Stretchable Electronics, 2018 (ISFSE 2018), Wuhan, China, from June 29 to 30, 2018
19、(特邀报告) Wentao Xu, Materials for artificial synapses, The 1st International Conference on Frontiers of Electronic Science and Technology, Chengdu, China (May 12-16, 2018)
18、(口头报告) Wentao Xu, Sung-Yong Min, Hyunsang Hwang, Tae-Woo Lee, “Printed organic nanowire synaptic transistors” SPIE Organic Photonics + Electronics, San Diego, California, USA (August 2015)
17、Dong-Wook Kim, Sung-Yong Min, Su-Kyoung Kim, Wentao Xu, Tae-Woo Lee, “Correlation between Morphology of Conjugated Polymer and Ion Diffusion in Ion Gel-gated Poly(3-hexylthiophene) Organic Electrochemical Transistor and its application to Synaptic Transistor” International Conference on Electronic Materials and Nanotechnology for Green Environment 2014 (ENGE2014), Jeju, S. Korea (Nov 2016)
16、S.-K. Kim, S.-Y. Min, D.-W. Kim, Wentao Xu, Tae-Woo Lee, “Effects of ionic liquids on synaptic behaviors in organic nanowire-based artificial synaptic transistor” International Conference on Electronic Materials and Nanotechnology for Green Environment 2014 (ENGE2014), Jeju, S. Korea (Nov 2016)
15、Hong-Kyu Seo, Tae-Sik Kim, Sang-Hoon Bae, Wentao Xu, Rishi Raj, Hee-Cheul Choi, Jong-Hyun Ahn, Tae-Woo Lee, “Practical Electronics Applications of Graphene Films Converted from Cheap Solid Carbon Sources” The 2nd Korean Graphene Symposium, Buyeo, Korea (March 2015)
14、Himchan Cho, Su-Hun Jeong, Sung-Yong Min, Tae-Hee Han, Min-Ho Park, Young-Hoon Kim, Youngjun Lee, Wentao Xu, Tae-Woo Lee, “Simple Large-Area Pixel Patterning for Flexible Organic Light-Emitting Diodes by Electro-Hydrodynamic Organic Nanowire Printing” Materials Research Society Fall Meeting, Boston, USA (December 2014)
13、(口头报告) Wentao Xu, Sung-Yong Min, Tae-Sik Kim, Tae-Woo Lee, “Ion-gel Gated E-nanowire Synaptic Transistors” International Conference on Electronic Materials and Nanotechnology for Green Environment 2014 (ENGE2014), Jeju, S. Korea (Nov 2014)
12、Hong-Kyu Seo, Tae-Sik Kim, Sang-Hoon Bae, Wentao Xu, Rishi Raj, Hee-Cheul Choi, Jong-Hyun Ahn, Tae-Woo Lee, “Graphene Films Converted from Cheap Solid Carbon Sources for High-performance Electronic Devices” Recent Progress in Graphene Research 2014 (RPGR 2014), Taipei, Taiwan (Sep 2014)
11、Tae-Hee Han, Sungjoo Kwon, Wentao Xu, Tae-Woo Lee, “Air-Stable Solution-Processed Chemical Doping for Graphene Electronics” The Korean Society of Industrial Engineering Chemistry Spring Meeting, Jeonju, S. Korea (Oct 2014)
10、Wentao Xu, Tae-Seok Lim, Hong-Kyu Seo, Sung-Yong Min, Himchan Cho, Min-Ho Park, Young-Hoon Kim, and Tae-Woo Lee, “N-DMBI-doped graphene field-effect transistors with enhanced electron mobility and air-stability”, Materials Research Society Fall Meeting, Boston, USA (December 2013)
9、Hong-Kyu Seo, Tae-Sik Kim, Sang-Hoon Bae, Wentao Xu, Sung-Young Lee, Hee-Cheul Choi, Jong-Hyun Ahn, and Tae-Woo Lee, “Electronics Applications of Graphene Films Converted from Coal Tar Pitch” The 5th Asian Conference on Organic Electronics, Pohang, S. Korea (November 2013)
8、Wentao Xu, Shi-Woo Rhee, “Low-temperature curable copolymer gate insulator for hysteresis-free organic field-effect transistors and metal-insulator-semiconductor capacitors”, FAPS polymer congress 2011, Beijing, China (May 2011)
7、Wentao Xu, Chang Guo, Shi-Woo Rhee, “Flexible organic transistors functioned at low-temperature cross-linked high-k polymer cyanoethylated pullulan as a gate insulator on stainless steel substrates”, Materials Research Society Fall Meeting, Boston, USA (November 2010)
6、Wentao Xu, Shi-Woo Rhee, “High performance pentacene field-effect transistors by using CEP/Al2O3 bilayer gate insulator”, Korea-Japan Symposium on Materials & Interface, Yeosu, S. Korea (October 2010)
5、Wentao Xu, Chang Guo, Dongjin Yun, Shi-Woo Rhee, “A low-voltage operated organic field-effect transistor with high mobility and steep subthreshold slope via leakage current suppression”, International Union of Materials Research Society-International Conference on Electronic Materials (IUMRS-ICEM), Yeosu, S. Korea (August 2010)
4、Wentao Xu, Chang Guo, Shi-Woo Rhee, “Hysteresis-free organic field-effect transistors with a polymer gate insulator cross-linked by Michael addition reaction”, International Symposium on Advanced Display Materials and Devices (ADMD), Daegu, S. Korea (June 2010)
3、(口头报告) Wentao Xu, Sanghoon Lim, Shi-Woo Rhee, “Hysteresis-free organic field-effect transistors with a high dielectric strength cross-linked polyacrylate copolymer gate insulator”, Material Research Society of Korea Fall Meeting, Pohang, S. Korea (November 2009)
2、Wentao Xu, Chanhong Chung, Younghwan Kwon, “Living ring opening polymerization (ROMP) to systhesize novel diblock copolymers”, The Korean Society of Industrial Engineering Chemistry Spring Meeting, Daegu, S. Korea (May 2007)
1、Wentao Xu, Chanhong Chung, Younghwan Kwon, “Synthesis of novel amphiphilic diblock copolymers containing polyhedral oligomeric silsesquioxane (POSS) using ring opening metathesis copolymerization” The Korean Society of Industrial Engineering Chemistry Spring Meeting, Jeonju, S. Korea (May 2006))
专利列表:
1、 [授权专利] 徐文涛,马明雪,倪尧,一种用于模拟生物突触神经递质多路复用的双兴奋性人工突触器件的制备方法,中国发明专利,申请号:202011073522.6(授权日期:2023年1月24日)
2、 [授权专利] 徐文涛,卫欢欢,于海洋,龚江东,一种基于Ti3C2-MXene/电解质结构的人工突触器件的制备方法,中国发明专利,申请号:202011019085.X(授权日期:2022年10月4日)
3、 [授权专利] 徐文涛,王子贤,杨露,一种基于P3HT纳米线的三端三维人造突触电子器件的制备方法,中国发明专利,授权号:ZL202110625803.6(授权日期:2022年08月19日)
4、 [授权专利] 徐文涛,龚江东,李跃龙,于海洋,周芯,卫欢欢,一种基于单晶钙钛矿的两端人工突触及其制备方法,中国发明专利,授权号:ZL202010743126.3(授权日期:2022年04月29日)
5、 [授权专利] 徐文涛,刘璐,一种数码可控打印IZO纳米线电极的方法,中国发明专利,授权号:ZL202010261612.1(授权日期:2022年03月15日)
6、 [授权专利] 徐文涛,一种耐应力拉伸的柔性膜的制备方法,中国发明专利,授权号:ZL202010261611.7(授权日期:2021年8月3日)
7、 [授权专利] Tae-Woo Lee, Lee Yeong Jun, Zhenan Bao, Kim-Yeong In, Alex Chortos, Wentao Xu,(人工感觉神经系统装置,包括人工突触)Artificial Sensory Nervous System Device Including Artificial Synapse,韩国专利注册号:102246807(注册日期: 2021年4月30日)
8、 [授权专利] 徐文涛,于海洋,龚江东,一种基于有机/无机杂化钙钛矿的两端人造突触电子器件的制备方法,中国发明专利,授权号:ZL201910166108.0(授权日期: 2020年11月27日)
9、 [授权专利] Tae-Woo Lee, Wentao Xu, Sung-Yong Min, Hyunsoo Moon, Kyo-Han Ahn, ‘메모리 소자용 유기 도핑 재료, 이를 포함하는 비휘발성 메모리 소자 및 이의 제조방법(有机掺杂剂及其掺杂的半导体材料在非易失性存储器上的应用)’or ‘Organic doping material for memory device, nonvolatile memory device including the same and method of manufacturing the same’, 韩国专利授权号:1016361370000(授权日期: 2016年6月28日)
10、 [授权专利] Shi-Woo Rhee, Wentao Xu, ‘고분자 게이트 절연막의 제조방법(高介电常数)高分子栅极绝缘层的制造方法)’ or ‘Method for preparing a polymer gate dielectric’, 韩国专利注册号:1011006470000(注册日期: 2011年12月23日)
11、 徐文涛,李玥,基于人工突触器件构建的仿生神经环路模体,中国发明专利,申请号:202310589058.3(申请日期,2023年5月24日)
12、 徐文涛,倪尧,刘甲奇,韩弘,刘璐,一种具有色/电双权重调控的人工突触器件,中国发明专利,申请号:202310287657.X(申请日期,2023年3月23日)
13、 徐文涛,屈尚达,一种电学性能可调控的ZTO纤维基突触器件的制备方法,中国发明专利,申请号:202310283261.8(申请日期,2023年3月22日)
14、 徐文涛,屈尚达,一种本征突触可塑性可调控的ZTO半导体纤维基突触晶体管的制备方法,中国发明专利,申请号:2023102832514(申请日期,2023年3月22日)
15、 徐文涛,杨露,王子贤,一种基于SnO2纳米线突触器件的味觉神经形态系统及其制备方法和应用,中国发明专利,申请号:202211451400.5(申请日期,2022年11月18日)
16、 徐文涛,刘甲奇,一种基于三维突触的人工环路模体结构及其制备方法,中国发明专利,申请号:202211118930.8(申请日期,2022年9月13日)
17、 徐文涛,刘俊池,蒋程鹏,杨露,一种三维立体柔性结构触觉传感器及其制备方法,中国发明专利,申请号:202210871580.6(申请日期:2022年7月24日)
18、 徐文涛,刘甲奇,李跃龙,龚江东,蒋程鹏,一种基于室温钙钛矿的柔性人工突触及其制备方法,中国发明专利,申请号:202210533921.9(申请日期,2022年5月17日)
19、 徐文涛,刘璐,一种具有低能耗的双极性突触晶体管及其制备方法,中国发明专利,申请号:202210418755.8(申请日期:2022年4月20日)
20、 徐文涛,刘璐,倪尧,一种具有长时程突触可塑性的突触晶体管及其制备方法,中国发明专利,申请号:202210418786.3(申请日期:2022年4月20日)
21、 徐文涛,屈尚达,孙林,一种数码可控打印ITO纳米导线的方法,中国发明专利,申请号:202210418781.0(申请日期:2022年4月20日)
22、 徐文涛,屈尚达,孙林,一种基于数码可控打印ITO纳米线的三端人工突触器件及其制备方法,中国发明专利,申请号:202210417751.8(申请日期:2022年4月20日)
23、 徐文涛,王子贤,杨露,一种数码可控打印SnO2半导体纳米线的方法,中国发明专利,申请号:202210319768.X(申请日期:2022年3月30日)
24、 徐文涛,杨露,王子贤,一种数码可控打印Ag纳米线的方法,中国发明专利,申请号:202210245776.4(申请日期:2022年3月14日)
25、 徐文涛,杜怡,一种基于纺织微结构的柔性触觉传感器的制备方法,中国发明专利,申请号:202210219199.1(申请日期:2022年3月8日)
26、 徐文涛,郭科鑫,一种具备纳米沟道的人工突触器件的制备方法,中国发明专利,申请号:202210215494.X(申请日期:2022年3月7日)
27、 徐文涛,龚江东,卫欢欢,一种基于聚酰亚胺新型栅绝缘层的突触晶体管器件及其制备方法,中国发明专利,申请号:202110942542.0(申请日期:2021年8月17日)
28、 徐文涛,龚江东,卫欢欢,一种基于PIN异质结两端人工突触及其制备方法,中国发明专利,申请号:202110893895.6(申请日期:2021年8月5日)
29、 徐文涛,王子贤,杨露,一种基于P3HT纳米线的三端三维人造突触电子器件的制备方法,中国发明专利,申请号:202110625803.6(申请日期:2021年6月4日)
30、 徐文涛,徐雯龙,刘璐,一种数码可控打印铜纳米导线的方法,中国发明专利,申请号:202010900271.8(申请日期:2020年9月1日)
31、 徐文涛,郭科鑫,卫欢欢,一种基于纳米氧化物薄膜/电解质垂直结构的人工突触电子器件的制备方法,中国发明专利,申请号:202011114499.0(申请日期:2020年10月19日)
32、 徐文涛,马明雪,倪尧,一种用于模拟生物突触神经递质多路复用的双兴奋性人工突触器件的制备方法,中国发明专利,申请号: 202011073522.6(申请日期:2020年10月9日)
33、 徐文涛,卫欢欢,于海洋,龚江东,一种基于Ti3C2-MXene/电解质结构的人工突触器件的制备方法,中国发明专利,申请号: 202011019085. X(申请日期:2020年9月23日)
34、 徐文涛,龚江东,李龙,于海洋,周芯,卫欢欢,一种基于单晶钙钛矿的两端人工突触及其制备方法,中国发明专利,申请号:202010743126.3(申请日期:2020年7月29日)
35、 徐文涛,刘璐,徐雯龙,一种数码可控打印P (VDF-TrFE)纳米线阵列的方法,中国发明专利,申请号:202010261605.1(申请日期:2020年4月4日)
36、 徐文涛,刘璐,一种数码可控打印IZO纳米线电极的方法,中国发明专利,申请号:202010261604.7(申请日期:2020年4月4日)
37、 徐文涛,刘璐,一种数码可控打印IZO半导体纳米线的方法,中国发明专利,申请号:202010261612.1(申请日期:2020年4月4日)
38、 徐文涛,徐雯龙,一种超疏水熔体电纺布的制备方法,中国发明专利,申请号:202010262017.X (申请日期:2020年4月6日)
39、 徐文涛,韩弘,一种基于P3HT超薄膜的三端仿生突触电子器件,中国发明专利,申请号:201910559549.7(申请日期:2019年6月26日)
40、 徐文涛,陈一航,韩弘,基于P3HT纳米线的三端仿生突触电子器件,中国发明专利申请号:201811219439.8(申请日期: 2018年10月19日)
41、 徐文涛,马明雪,一种有机纳米离子/电子杂化的两端神经仿生电子器件的制备方法,中国发明专利,申请号:20181108851.2(申请日期: 2018年9月17日)
42、 Tae-Woo Lee, Wentao Xu, Sung-Yong Min, ‘시냅스 모방 소자 및 이의 제조방법 (模仿神经突触的电子器件及其制造方法)’ or ‘Device imitating synaptic and method of manufacturing thereof’, PCT 国际专利申请号:PCT/KR2014/012656(申请日期:2014年12月22日)
43、 Tae-Woo Lee, Wentao Xu, Sung-Yong Min, Hyunsoo Moon, Kyo-Han Ahn, ‘메모리 소자용 유기 도핑 재료, 이를 포함하는 비휘발성 메모리 소자 및 이의 제조방법(有机掺杂剂及其掺杂的在非易失性存储器上的应用)’ or ‘Organic dopant and doped semiconductors with the same for nonvolatile memory’, PCT 国际专利申请号:PCT/KR2014/012670(申请日期:2014年12月23日)
44、 Tae-Woo Lee, Wentao Xu, Sung-Yong Min, ‘시냅스 모방 소자 및 이의 제조방법 (模仿神经突触的电子器件及其制造方法)’ or ‘Device imitating synaptic and method of manufacturing thereof’, 韩国专利申请号:10-2014-0104279(申请日期: 2014年8月12日)
45、 Tae-Woo Lee, Wentao Xu, Yeongjun, Lee, ‘멤리스터 소자 및 그 제조방법(纳米线忆阻器件及其制造方法)’ or ‘Memristor element and method for manufacturing the same’, 韩国专利申请号:10-2014-0104669(申请日期: 2014年8月12日)
专著列表:
2. Wentao Xu, Hong Han, Shuo Zhang, Zhipeng Xu, Yao Ni, Huanhuan Wei. Low-Dimensional Conjugated Polymer-Based Artificial Synapses [M]// Sergey Y. Yurish. Advances in Intelligent Systems: Reviews, Vol. 2. IFSA Publishing, 2021, Spain. ISBN: 978-84-09-29876-1.
1. Wentao Xu, & Yao Ni. Memory characteristics and mechanisms in transistor-based memories [M]// S. -T. Han, & Y. Zhou. Photo-Electroactive Non-Volatile Memories for Data Storage and Neuromorphic Computing. Elsevier, 2020, United Kingdom. ISBN: 978-0-12-819717-2.
