唐帅

副教授

[email protected]

博士生导师

国家海外高层次青年人才项目入选者,

丝袜性爱 百人计划引进人才,

主要从事真空微纳电子学、原位电子显微学、低维纳米材料制备与表征的研究。

联系方式:

邮箱:[email protected]

研究团队

光电材料与技术国家重点实验室—“微纳结构电子光子与器件”团队(学术带头人: 邓少芝 教授)。

招生/招聘专业:

电子科学与技术、集成电路工程,欢迎感兴趣的博士生、硕士生、本科生及博士后加入,有意者请邮件联系(目前还有2025年度研究生指标,欢迎联系)

学术兼职和社会服务

SCI期刊 Journal of Materials Science & Technology青年编委(中科院1区,影响因子:10.9)

SCI期刊Progress in Natural Science Materials International青年编委(中科院2区,影响因子:4.7)

SCI期刊Nanomaterials场发射专题客座编辑(影响因子:5.7)

《真空科学与技术学报》真空微纳电子与器件专刊客座编辑

中国真空学会高级会员

教育经历 

2012年9月-2017年12月,丝袜性爱    微电子学与固体电子学  工学博士 (导师:许宁生 院士、邓少芝 教授)

2008年9月-2012年6月,  丝袜性爱    微电子学 (逸仙班)    工学学士

授课课程

微纳电子器件

大学物理实验

电子发射方法

研究方向

1,场发射点电子源的研究与应用 (高时空分辨/自旋极化/冷冻电子显微镜、X射线管、芯片多束检测/加工设备、扫描隧道显微镜、低能电子衍射等)

2,纳米材料原位SEM/TEM电学、热学性质研究 (石墨烯、碳管、纳米线、纳米锥、二维纳米片等)

3,低维纳米材料的制备、表征与应用 (自下而上:CVD生长;自上而下:FIB精细结构制备)

我们致力于为高端电子显微镜及芯片检测/加工设备开发更高分辨、更高通量及更稳定发射的点电子源

我们也致力于用高分辨电子显微技术原位探索材料在纳米、原子尺度的电学特性

我们的研究非常注重国际合作交流,目前与日本国立材料研究所(NIMS)、美国北卡罗来纳大学教堂山分校(UNC)等顶级大学、研究机构有着良好的合作关系。

科研项目

1. 国家海外高层次人才青年项目,2024-2026,主持

2. 国家科技部重点研发计划“基础科研条件与重大科学仪器设备研发”,2023-2026,课题负责人

3. 国家自然科学基金青年科学基金项目,2024-2026,主持

4. 广东省重点领域研发计划“精密仪器设备”,2021-2024,项目参与单位负责人

5. 广州市基础与应用基础研究专题,2024-2026,主持

6. 丝袜性爱 基本科研业务费-青年教师重点培育项目,2023-2024,主持

7. 丝袜性爱 百人计划引进人才启动经费,2022年6月 - 2025年6月,主持

8. NIMS-Denka先进材料研究中心合作项目(日本)及NIMS-Denka-JEOL(日本)三社联合研究项目,碳化铪纳米线/六硼化镧纳米锥作为下一代SEM/TEM点电子源的应用研究,2018年4月 - 2022年5月,学术骨干、第一参加者(Denka是世界上最大的点电子源供应商,点电子源市场份额占据全球的70%)

9. 国家纳米重大科学研究计划,高电流密度大电流纳米冷阴极及其应用基础研究, 2013年1月 - 2017年12月, 学术骨干

10. 国家自然科学基金面上项目,石墨烯冷阴极大电流场发射损伤机制的微观原位研究,2017年1月 - 2020年12月, 学术骨干

11. 广东省自然科学基金, 石墨烯冷阴极大电流场发射的破损微观机制研究, 2016年6月 - 2019年6月,学术骨干

代表性科研成果

发表SC期刊论文及会议论文50余篇,申请国内外发明专利10余项。全部文章列表请见//www.researchgate.net/profile/Shuai-Tang-9/research。

论文:

  1. Y. M. Huang, S. Tang*, S. Z. Deng, H. K. Guan, H. N. Zhao, R. Z. Zhan, L. Gong, P. Liu, Y. Zhang, Y. Shen. Effect of hydrogen plasma pretreatment on the nucleation and growth of vertical few-layer graphene prepared by microwave plasma chemical vapor deposition, Carbon, 2025, 235:120061. (通讯作者,  IF=10.5中科院大类2区TOP, 2025)
  2. S. Tang, J. Tang*, Y. M. Wu, Y.-H. Chen, J. Uzuhashi, T. Ohkubo, M. Takeguchi, L.-C. Qin*. Stable and high current emission of electrons from a HfC nanoneedle field-emitter fabricated by focused ion beam, Vacuum, //doi.org/10.1016/j.vacuum.2025.114224. (第一作者,  IF=3.8, 中科院大类2区, 2025)
  3. Y. M. Wu, J. Tang*, S. Tang, Y.-H. Chen, T.-W. Chiu, M. Takeguchi, A. Hashimoto, L.-C. Qin. Stable Field Emissions from Zirconium Carbide Nanoneedle Electron Source. Nanomaterials, 2025, 15: 93. (第三作者,  IF=4.4, 中科院大类3区, 2025)
  4. Y. M. Huang, S. Tang*, M. K. Gou, H. N. Zhao, Y. Shen, Y. Zhang, J. C. She, J. Chen, S. Z. Deng. Field Emission Characteristics from Vertical Few-Layer Graphene Growth on Graphite Substrate. 2024 37th International Vacuum Nanoelectronics Conference (IVNC). (通讯作者,  EI收录2024)
  5. J. H. Zhong, S. Tang*, M. K. Gou, Y. Shen, Y. Zhang, Y. M. Huang, J. C. She, J. Chen, N. S. Xu, S. Z. Deng. A Nano-Focus X-Ray Source with Nanoneedle Cold Cathode by Simulation. 2024 37th International Vacuum Nanoelectronics Conference (IVNC). (通讯作者,  EI收录2024)
  6. Y. M. Wu, J. Tang*, S. Tang, Y.-H. Chen, T.-W. Chiu, M. Takeguchi, L.-C. Qin*. Stable field emission from single-crystalline zirconium carbide nanowires. Nanomaterials, 2024, 14: 1567. (第三作者,  IF=4.4, 中科院大类3区, 2024)
  7. S. Tang*, J. Tang, E. Okunishi, J. Uzuhashi, T. Ohkubo, M. Takeguchi, L.-C. Qin. A LaB6 Nanoneedle Field-Emission Electron Source for Stable Imaging with Atomic Resolution in a Transmission Electron Microscope. 2023 37th International Vacuum Nanoelectronics Conference (IVNC). (第一&通讯作者,  EI收录2023)
  8. Y. Y. Chen, S. Tang, Y. Shen*, H. J. Chen, S. Z. Deng. A Tunable Photo-Electric co-Excited Point Electron Source: Low-Intensity Excitation Emitting and Structure-Modulated Spectrum-Selecting. Nanoscale,  2023, 15: 8643-8653. (第二作者中科院大类二区Top,IF=6.7, 2023)

  9. S. Tang, J. Tang*, E. Okunishi, Y. Ninota, A. Yasuhara, J. Uzuhashi, T. Ohkubo, M. Takeguchi, J. S. Yuan, L.-C. Qin*. A stable LaB6 nanoneedle field-emission electron source for atomic resolution imaging with a transmission electron microscope, Materials Today, 2022,57:35-42. (第一作者,  IF=26.943中科院大类1区TOP, 2022)

    该研究工作同时被日本国立材料研究所(NIMS)和日本电子公司(JEOL)在官网丝袜性爱以最新新闻及热点论文的形式报道
    日本国立材料研究所(NIMS)://www.nims.go.jp/eng/news/article/2022/202207050.html
    日本电子公司(JEOL)://www.jeol.co.jp/en/news/detail/20220705.5712.html

  10. S. Tang, J. Tang*, Y. M. Wu, Y.-H. Chen, J. Uzuhashi, T. Ohkubo, L.-C. Qin*. Stable field emission current from a CeB6 nanoneedle point electron source, Nanoscale, 2021, 13: 17156-17161. (第一作者,  IF=6.895中科院大类1区TOP, 2021)
  11. S. Tang, J. Tang*, J. Uzuhashi, T. Ohkubo, W. Hayami, J. S. Yuan, M. Takeguchi, M. Mitome, L.-C. Qin*. A stable LaB6 nanoneedle field-emission point electron source, Nanoscale Advances, 2021, 3: 2787-2792. (第一作者,  IF=4.553中科院大类2区, 2021 )
  12. S. Tang, Y. Zhang*, P. Zhao, R. Z. Zhan, J. Chen, S. Z. Deng*. Realizing the large current field emission characteristics of single vertical few-layer graphene by constructing a lateral graphite heat dissipation interface. Nanoscale, 2021, 13: 5234-5242. (第一作者, 首封面文章,IF=6.895中科院大类1区TOP,2021)  
  13. S. Tang, J. Tang*, T.-W. Chiu, J. S. Yuan, D.-M. Tang, M. Mitome, F. Uesugi, Y. Nemoto, M. Takeguchi, L.-C. Qin*. Electrical conduction and field emission of single-crystalline GdB44Si2 nanowire. Nanoscale, 2020, 12: 18263-18268. (第一作者, IF=6.860中科院大类1区TOP,2020)  
  14. S. Tang, J. Tang*, T.-W. Chiu, J. Uzuhashi , D.-M. Tang , T. Ohkubo , M. Mitome , F. Uesugi , M. Takeguchi, L.-C. Qin*. A controllable and efficient method for making single HfC nanowire field-emission point electron source aided by low keV FIB milling. Nanoscale, 2020, 12: 16770-16774 . (第一作者内背封面文章,IF=6.860中科院大类1区TOP,2020)
  15. S. Tang, J. Tang*, T.-W. Chiu, W. Hayami, J. Uzuhashi, T. Ohkubo, F. Uesugi, M. Takeguchi, M. Mitome, L.-C. Qin*. A HfC nanowire point electron source with oxycarbide surface of lower work function for high-brightness and stable field-emission. Nano Research, 2020, 13: 1620-1626 (第一作者, IF=8.515中科院大类1区TOP,2020)
  16. S. Tang, S. Z. Deng, P. Zhao, R. Z. Zhan, J. Chen, S. Z. Deng Y. Zhang*. Self-optimizing effect of a few-layer graphene’s top-edge structure during field electron emission observed by in situ TEM. ACS Applied Materials & Interfaces, 2020, 12: 16815-16821 . (第一作者, IF=8.456中科院大类1区TOP,2020)
  17. S. Tang, Y. Zhang*, N. S. Xu, P. Zhao, R. Z. Zhan, J. Chen, S. Z. Deng*. Structure stability of few-layer graphene under high electric field. Carbon, 2019, 144: 202-205.(第一作者, IF=7.466中科院大类1区TOP,2019)
  18. S. Tang1, Y. Zhang1, N. S. Xu, P. Zhao, R. Z. Zhan, J. Chen, S. Z. Deng*. Pinhole evolution of few-layer graphene during electron tunneling and electron transport. Carbon, 2018, 139: 688-694. (第一作者(共一排第一位), IF=7.082中科院大类1区TOP,2018)
  19. S. Tang, Y. Zhang*, Y. Tian, S. Y. Jin, P. Zhao, F. Liu, R. Z. Zhan, S. Z. Deng, J. Chen, N. S. Xu. A two-dimensional structure graphene STM tips fabricated by microwave plasma enhanced chemical vapor deposition. Carbon, 2017, 121: 337-342. (第一作者, IF=6.337中科院大类1区TOP,2017)
  20. S. Tang, Y. Zhang*, N. S. Xu, R. Z. Zhan, L. Gong, P. Zhao, J. Chen, C. L. Liang, J. Chen, J. C. She, S. Z. Deng*. In situ study of graphene crystallinity effect on field electron emission characteristics. Journal of Vacuum Science & Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phenomena, 2017, 35(2): 02C107. (第一作者, IF=1.573中科院大类3区,2017)
  21. A. Chen, Y. Shen*, T. Cui, W. Y. Feng, R. Z. Zhan, Y. L. Pei, S. Tang, H. J. Chen, S. Z. Deng. Needle-Shaped Single-Crystalline Molybdenum Micro-Nano Structure with High Conductivity and Excellent Field Emission Properties: Implications for Large-Current Cold-Cathodes. ACS Applied Nano Materials, 2023, 6: 12486-12496.
  22. Y. Y. Chen, S. Tang, Y. Shen*, H. J. Chen, S. Z. Deng. A tunable photo-electric co-excited point electron source: low-intensity excitation emission and structure-modulated spectrum-selection. Nanoscale, 2023, 15: 8643-8653.
  23. W. Hayami*, S. Tang, J. Tang, L.-C. Qin. Effects of low work-function lanthanum oxides on stable electron field emissions from nanoscale emitters. Nanoscale Advances, 2022, 4: 4669-4676. (第二作者,影响因子5.598中科院大类2区,2022)
  24. R. Gao, J. Tang*, S. Tang, K. Zhang, K. Ozawa, L.-C. Qin. Tin-cobalt bimetals in 2D leaf-like MOF-derived carbon for advanced lithium storage applications. Electrochimica Acta, 2022, 410: 140036. (第三作者, IF=6.901中科院大类2区TOP,2022)
  25. W. Hayami, S. Tang, T.-W. Chiu, J. Tang. Reduction in work functions of transition-metal carbides and oxycarbides upon oxidation. ACS Omega, 2021, 6: 14559–14565. (第二作者, IF=3.512中科院大类3区,2021)
  26. R. Gao, J. Tang*, S. Tang, K. Zhang, K. Ozawa, L.-C. Qin. Biomineralization-inspired: rapid preparation of silicon-based composite as high-performance lithium-ion battery anode. Journal of Materials Chemistry A, 2021, 9: 11614-11622 (第三作者, IF=11.301中科院大类一区,2020) .
  27. X. Yu, T. Liao, J. Tang*, K. Zhang, S. Tang, R. S. Gao, S. Q. Lin, L.-C. Qin. Edge engineering in 2D molybdenum disulfide: simultaneous regulation of lithium and polysulfides for stable lithium-sulfur batteries. Advanced Energy and Sustainability Research, 2021, 2: 2100053. (第五作者, 新期刊IF未知, 2021)
  28. L. Kang, J. Tang*, S. Tang, K. Zhang, Y. Hato, Y. Takeda, L.-C. Qin. Reduced graphene oxide decorated with crystallized cobalt borate nanoparticles as an anode in lithium ion capacitors. Chemical Physics Letters, 2020, 759: 137964. (第三作者, IF=2.029中科院大类三区,2020)
  29. T.-W. Chiu, J. Tang*, S. Tang, J. S. Yuan, L.-C. Qin. Reduced work function and improved field emission stability of ZrC nanowires upon surface oxidation. Applied Physics Letters, 2020, 117(5): 053101. (第三作者, IF=3.597中科院大类二区TOP,2020)
  30. T.-W. Chiu, J. Tang*, S. Tang, J. S. Yuan, L.-C. Qin. Synthesis and Field Emission of ZrC Nanowire. Materials Today Communications, 2020, 25: 101240 (第三作者,IF=1.970中科院大类3区,2020)
  31. T.-W. Chiu, J. Tang*, S. Tang, J. S. Yuan, L.-C. Qin. Growth and field-emission of single-crystalline hafnium carbide nanowire. Physica Status Solidi a-Applications and Materials Science, 2020, 217: 2000007. (第三作者首封面文章,IF=1.606中科院大类4区,2020)
  32. R. Gao, J. Tang*, X. Yu, S. Tang, K. Ozawa, T. Sasaki, L.-C. Qin. In situ synthesis of MOF-derived carbon shells for silicon anode with improved lithium-ion storage. Nano Energy, 2020, 70: 104444. (第四作者, IF=15.548中科院大类1区TOP,2020)
  33. P. Zhao, Y. Zhang, S. Tang, R. Z. Zhan, J. C. She, J. Chen, S. Z. Deng*. A universal method to weld individual one-dimensional nanostructures with a tungsten needle based on synergy of the electron beam and electrical current. Nanomaterials, 2020, 10: 469. (第三作者, IF=4.034中科院大类2区,2020)
  34. P. Zhao, Y. Zhang, S. Tang, R. Z. Zhan, J. C. She, J. Chen, N. S. Xu, S. Z. Deng*. Effect of piezoresistive behavior on electron emission from individual silicon carbide nanowire. Nanomaterials, 2019, 9: 981. (第三作者, IF=4.034中科院大类2区,2019)
  35. Z. F. Lin, R. Z. Zhan, L. Y. Li, H. H. Liu, S. F. Jia, H. J. Chen, S. Tang, J. C. She, S. Z. Deng, N. S. Xu, J. Chen*. Defect-concentration dependence of electrical transport mechanisms in CuO nanowires. RSC advances, 2018, 8: 2188-2195. (第七作者, IF=2.936中科院大类3区,2018)
  36. Y. Shen, N. S. Xu, S. Z. Deng*, S. Tang, Y. Zhang, F. Liu, J. Chen. Effect of nanostructure building formation on high current field emission properties in individual molybdenum nanocones. ACS applied materials & interfaces, 2015, 7: 3825-3833. (第四作者, IF=7.145中科院大类1区TOP,2015)
  37. Y. Zhang, S. Tang, D. L. Deng, S. Z. Deng*, J. Chen, N. S. Xu. Growth direction manipulation of few-layer graphene in the vertical plane with parallel arrangement. Carbon, 2013, 56: 103-108. (第二作者, IF=5.868中科院大类1区TOP,2013)
  38. Y. Zhang, J. L. Du, S. Tang, P. Liu, S. Z. Deng*, J. Chen, N. S. Xu. Optimize the field emission character of a vertical few-layer graphene sheet by manipulating the morphology. Nanotechnology, 2011, 23: 015202. (第三作者, IF=3.848中科院大类1区TOP,2011, Physics World杂志评价本工作是“20个石墨烯的潜在应用之一”,被引次数108,截止到2022年6月)
  39. S. Tang*, J. Tang*, E. Okunishi, J. Uzuhashi, T. Ohkubo, M. Takeguchi, L.-C. Qin. A LAB6 Nanoneedle Field-Emission Electron Source for Stable Imaging with Atomic Resolution in a Transmission Electron Microscope. IEEE 36th International Vacuum Nanoelectronics Conference (IVNC). IEEE, 2023: 163-165.(第一&通讯作者, EI收录)
  40. S. Tang*, J. Tang*, T.-W. Chiu, W. Hayami, L.-C. Qin. A HfC nanowire field emission point electron source. 34th International Vacuum Nanoelectronics Conference (IVNC). IEEE, 2021: 1-2, Lyon, France.(第一&通讯作者, EI收录)
  41. S. Tang, Y. Zhang*, S. Z. Deng, J. Chen, N. S. Xu*. Effect of crystallinity of graphene on its field emission character, 29th International Vacuum Nanoelectronics Conference (IVNC), IEEE, 2016: 1-2, Vancouver, Canada.(第一作者, EI收录)
  42. S. Tang, Y. Zhang*, S. Z. Deng, J. Chen, N. S. Xu*. Growth of a single graphene sheet on a tungsten tip, 27th International Vacuum Nanoelectronics Conference (IVNC), July 6-10, 2014, Engelberg, Swetzerland. (第一作者, EI收录)
  43. Y. Zhang, R. Z. Zhan, S. Tang, N. S. Xu, J. Chen, S. Z. Deng*. In-situ Characterization of Structure Evolution of Graphene During Field Emission. 2018 31st International Vacuum Nanoelectronics Conference (IVNC). IEEE, 2018: 1-2. (第三作者, EI收录)
  44. P. Zhao, Y. Zhang, S. Tang, J. Chen, J. C. She, N. S. Xu, S. Z. Deng*. Field Emission Properties of a Single Silicon Carbide Nanowire. 2018 31st International Vacuum Nanoelectronics Conference (IVNC). IEEE, 2018: 1-2. (第三作者, EI收录)
  45. Y. Zhang, P. Liu, S. Tang, J. L. Du, S. Z. Deng*, J. Chen, N. S. Xu. Field emission characteristics of vertical few-layer graphene with different shapes. 2011 24th International Vacuum Nanoelectronics Conference. IEEE, 2011: 181-182. (第三作者, EI收录)
  46. 唐帅,张宇*,邓少芝,陈军,许宁生*,不同形貌的直立少层石墨烯的场发射特性研究,中国电子学会真空电子学分会第十九届学术年会,2013年8月21日-24日,安徽黄山。(第一作者
  47. 唐帅,张宇*,邓少芝,陈军,许宁生,平行排列的直立少层石墨烯的可控制备研究,2012年中国真空学会学术年会,2012年9月21日-23日,甘肃兰州。(第一作者

专利:

  1. 邓少芝、唐帅、张宇、许宁生、陈焕君、陈军、佘峻聪,一种采用二维原子晶体结构材料的扫描隧道显微镜探针,专利号:CN106383250B。(已授权
  2. 唐 捷; 唐 帥; チュウ ターウェイ; 速水 渉; 秦 禄昌 ; エミッタ、それを用いた電子銃、それを用いた電子機器、および、その製 造方法, 专利号:JP7168269。(已授权
  3. 唐 捷; 唐 帥; チュー ターウェイ; 大久保 忠勝; 埋橋 淳; 宝野 和博; 秦 禄昌 ; エミッ、それを用いた電子銃、それを用いた電子機器、および、その製造方法, 专利号:JP7369473。(已授权
  4. 唐帅,苟明楷,邓少芝,许宁生,沈岩,张宇,陈军,佘峻聪, 冷阴极点电子源的发射面积测量方法和装置,专利号:2024106305083(已公开)
  5. 唐帅,苟明楷,邓少芝,许宁生,沈岩,张宇,陈军,佘峻聪, 场发射电子源性能指标确定方法和装置,专利号:2024106460483(已公开)
  6. 唐帅,钟俊浩,邓少芝,许宁生,沈岩,张宇,陈军,佘峻聪, 一种基于纳米原子尺度冷阴极的纳焦斑X射线管,专利号:2024105525438(已公开)
  7. TANG Jie; TANG Shuai; CHIU Ta-Wei; OHKUBO Tadakatsu; UZUHASHI Jun; HONO Kazuhiro; QIN Luchang; EMITTER, ELECTRON GUN USING SAME, ELECTRONIC DEVICE USING SAME, AND METHOD FOR MANUFACTURING SAME, 2020-10-20, WIPO, PCT/JP2020/039310。
  8. TANG Jie; TANG Shuai; CHIU Ta-Wei; HAYAMI Wataru; QIN Luchang; EMITTER, ELECTRON GUN USING SAME, ELECTRONIC DEVICE USING SAME,AND METHOD FOR PRODUCING SAME, 2020-6-29, WIPO, PCT/JP2020/025435。
  9. 唐 捷; 唐 帥; 速水 渉;秦 禄昌;エミッタ、それを用いた電子銃、それを用いた電子機器、および、その製造方法,2022-06-23,日本,特願2022-100768。
  10. 唐 捷; 唐 帥; チュー ターウェイ; 大久保 忠勝; 埋橋 淳; 宝野 和博; 秦 禄昌 ; エミッタ、それを用いた電子銃、それを用いた電子機器、および、その製造方法, 2019-12-12, 日本, 特願2019-224364。
  11. 茶谷 洋光; 石川 大介; 唐 捷; 大久保 忠勝; 唐 帥; 埋橋 淳; 宝野 和博 ; 電子源及びその製造方法、並びに電子源を備える装置, 2021-8-5, 日本, 特願2021-129281。

学术报告:

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  6. 2023 Cambridge MA, USA, 36th International Vacuum Nanoelectronics Conference, Oral report
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  9. 2021 Lyon, France, 34th International Vacuum Nanoelectronics Conferences, Oral report