孙旭辉 特聘教授,博士生导师
清华大学理学学士、硕士学位(1993,1996);香港城市大学博士学位(2002);加拿大西安大略大学化学系博士后(2003-2005);美国国家宇航局(NASA) Ames研究中心纳米技术中心博士后(2005-2007);NASA Ames研究中心先进研究实验室研究员(2007-2009);2009年加入苏州大学功能纳米与软物质材料研究院,特聘教授,博士生导师。
课题组内教师:文震副研究员、张浩助理研究员
研究领域:
纳米材料和纳米功能器件及其在新能源(纳米发电机、光解水、锂电池等)、柔性传感器及自驱动传感方面的应用研究,以及同步辐射技术及其在纳米材料研究中的应用。
主要成果和技术贡献:
现已在SCI收录国际期刊如J. Am. Soc. Chem.、Adv. Mater.、Angew. Chem. Int. Ed.、Nat. Commun.、Chem. Rev.、Energy Environ. Sci. 、ACS Nano、Adv. Funct. Mater.等上发表论文200余篇,撰写英文书(章节)5章。获得美国专利3项,PCT专利2项,申请中国专利80余项,已授权40余项。担任国际杂志IEEE Transaction on Nanotechnology副主编,Frontiers in Materials编委会委员,是国际电子电工学会高级会员、国际材料学会、国际X射线吸收谱学会会员,以及国家同步辐射实验室用户委员会副主任、上海光源用户委员会委员,国家纳米标准委员会苏州工作组副组长。2010 年入选“苏州市紧缺人才计划”。2011 年入选江苏省“333”人才工程计划。2012 年入选苏州工业园区科技领军人才。承担了国家重大研究计划课题负责人2项,国家基金委联合基金重点项目、重大研究计划培育项目、面上项目负责人等多项,还参与了国家863重大项目、国家02专项等。
招生方向:
本课题组招收硕士研究生、博士研究生及博士后,并邀请具有材料、化学、物理等背景的本科生参加本课题组的研究活动。具体招生方向包括材料学,化学、物理(凝聚态物理、电子),以及纳米专业。欢迎感兴趣的同学来我们课题组参观学习。如有疑问请随时联系[email protected]。
代表性论文:
(1) C. Chen, Z. Wen*, J. H. Shi, X. H. Jian, P. Y. Li, John T. W. Yeow*, X. H. Sun*, “Micro triboelectric ultrasonic device for acoustic energy transfer and signal communication”, Nat. Commun., 2020, 11, 4143.
(2) Y. J. Xia, S. Kashtanov, P. F. Yu, L. Y. Chang*, K. Feng, J. Zhong, J. H. Guo, X. H. Sun*, “Identification of dual-active sites in cobalt phthalocyanine for electrochemical carbon dioxide reduction”, Nano Energy, 2020, 67, 104163.
(3) N. N. Zhai, Z. Wen*, X. P. Chen, A. M. Wei, M. Sha, J. J. Fu, Y. N. Liu, J. Zhong*, X. H. Sun*, “Blue Energy Collection toward All‐Hours Self‐Powered Chemical Energy Conversion”, Adv. Energy Mater., 2020, 10(33), 2001041.
(4) C. Chen, Z. Wen*, A. Wei, X. Xie, N. Zhai, X. Wei, M. Peng, Y. Liu, X. H. Sun*, John T.W. Yeow*, “Self-powered on-line ion concentration monitor in water transportation driven by triboelectric nanogenerator”, Nano Energy, 2019, 62, 442-448.
(5) L. Han, M. Peng, Z. Wen, Y. Liu, Y. Zhang, Q. Zhu, H. Lei, S. Liu, L. Zheng*,X. H. Sun*, H. X. Li*, “Self-driven photodetection based on impedance matching effect between a triboelectric nanogenerator and a MoS2 nanosheets photodetector”, Nano Energy, 2019, 59, 492-499.
(6) K. H. Wang, X. Tong, Y. Zhou, H. Zhang, F. Navarro-Pardo, G. S. Selopal, G. Liu, J. Tang, Y. Q. Wang, S. Sun, D. L. Ma, Z. M. Wang, F. Vidal, H. G. Zhao*, X. H. Sun* and F. Rosei*, “Efficient solar-driven hydrogen generation using colloidal heterostructured quantum dots”, J. Mater. Chem. A, 2019, 7, 14079–14088.
(7) M. Peng, X. Xie, H. Zheng, Y. Wang, Q. Zhuo, G. Yuan, W. Ma, M. Shao, Z. Wen* and X. H. Sun*, “PbS Quantum Dots/2D Nonlayered CdSxSe1−x Nanosheet Hybrid Nanostructure for High-Performance Broadband Photodetectors” ACS Appl. Mater. Inter., 2018, 10 (50), 43887–43895
(8) Z. Wen, Y. Q. Yang, N. Sun, G. F. Li, Y. N. Liu, C. Chen, J. H. Shi, L. J. Xie, H. X. Jiang, D. Q. Bao, Q. Q. Zhuo, X. H. Sun*, “A Wrinkled PEDOT:PSS Film Based Stretchable and Transparent Triboelectric Nanogenerator for Wearable Energy Harvesters and Active Motion Sensors”, Adv. Funct. Mater., 28, 1803684 (2018).
(9) A. M. Wei, X. K. Xie, Z. Wen, H. C. Zheng, H. W. Lan, H. Y. Shao, X. H. Sun*, J. Zhong*, S. T. Lee, “Triboelectric Nanogenerator Driven Self-Powered Photoelectrochemical Water Splitting Based on Hematite Photoanodes” ACS Nano, 12, 8625 (2018).
(10) Y. Q. Yang, N. Sun, Z. Wen*, P. Cheng, H. C. Zheng, H. Y. Shao, Y. J. Xia, C. Chen, H. W. Lan, X. K. Xie, C. J. Zhou, J. Zhong, X. H. Sun*, S. T. Lee, “Liquid-Metal-Based Super-Stretchable and Structure-Designable Triboelectric Nanogenerator for Wearable Electronics”, ACS Nano, 12, 2027 (2018)
(11) Q. Q. Shen, X. K. Xie, M. F. Peng, N. Sun, H. Y. Shao, H. C. Zheng, Z. Wen, X. H. Sun*, “Self-Powered Vehicle Emission Testing System Based on Coupling of Triboelectric and Chemoresistive Effects”, Adv. Funct. Mater., 28, 1703420 (2018).
(12) K. Q. Nie, S. Kashtanov, Y. K. Wei, Y. S. Liu, H. Zhang, M. Kapilashrami, Y. F. Ye, P. A. Glans, J. Zhong, L. Vayssieres, X. H. Sun*, J. H. Guo*, “Atomic-scale Understanding of the Electronic Structure-Crystal Facets Synergy of Nanopyramidal CoPi/BiVO4 Hybrid Photocatalyst for Efficient Solar Water Oxidation”, Nano Energy, 53, 483 (2018).
(13) X. X. Lv, J. J. Deng, B. Q. Wang, J. Zhong, T. K. Sham, X. H. Sun*, X. L. Sun*, “g-Fe2O3@CNTs Anode Materials for Lithium Ion Batteries Investigated by Electron Energy Loss Spectroscopy”, Chem. Mater., 29, 3499 (2017).
(14) K. Feng, J. Zhong*, B. H. Zhao, H. Zhang, L. Xu, X. H. Sun*, S. T. Lee, “CuxCo1-xO Nanoparticles on Graphene Oxide as A Synergistic Catalyst for High-Efficiency Hydrolysis of Ammonia–Borane”, Angew. Chem. Int. Ed. 55, 11950 (2016).
(15) P. P. Zhang, H. Zhang, X. H. Sun*, “Uniform Porous Multilayer-Junction Thin Film for Enhanced Gas-Sensing Performance”, Nanoscale, 8 (2016), 1430-1436.
(16) Q. Q. Zhou, Q. Wang, Y. P. Zhang, D. Zhang, Q. L. Li, C. H. Gao, Y. Q. Sun, L. Ding, Q. J. Sun, S. D. Wang, J. Zhong, X. H. Sun*, S. T. Lee*, “Transfer-Free Synthesis of Doped and Patterned Graphene Films”, ACS Nano, 9, 594 (2015).
(17) J. Zhong, H. Zhang, X. H. Sun*, S. T. Lee*, “Synchrotron Soft X-ray Absorption Spectroscopy Study of Carbon and Silicon Nanostructures for Energy Applications”, Adv. Mater., 26, 7786 (2014).
(18) S. M. Zhang, P. P. Zhang, Y. Wang, Y. Y. Ma, J. Zhong, and Xuhui Sun*, “Facile Fabrication of Well-Ordered Porous Cu-doped SnO2 Thin Film for H2S Sensing”, ACS Appl. Mater. Inter., 6 (2014) 14975-14980.
(19) J. J. Deng, X. X. Lv, J. Gao, A. W. Pu, M. Li, X. H. Sun*, J. Zhong*, “Facile synthesis of carbon-coated hematite nanostructures for solar water splitting”, Energy Environ. Sci., 6, 1965 (2013).
(20) Jiujun Deng, Jun Zhong*, Aiwu Pu, Duo Zhang, Ming Li, Xuhui Sun*, Shuit-Tong Lee, “Ti-doped hematite nanostructures for solar water splitting with high efficiency” Journal of Applied Physics, 112 (2012), 084312.
(21) Mingfa Peng, Jing Gao, Pingping Zhang, Yang Li, Xuhui Sun*, Shuit Tong Lee , “Reductive Self-Assembling of Ag Nanoparticles on Germanium Nanowires and Their Application in Ultrasensitive Surface-Enhanced Raman Spectroscopy”, Chemistry of Materials, 23 (2011) 3296-3301.
(22) K. Li, R. Wu, P. Wilhite, V. Khera, S. Krishnan, X. H. Sun*, and C. Y. Yang, “Extraction of contact resistance in carbon nanofiber via interconnects with varying lengths”, Applied Physics Letters, 97 (2010) 253109.
(23) X. H. Sun*, B. Yu, G. Ng, S. Ju, and D. B. Janes, “Germanium Antimonide Phase-Change Nanowires for Memory Applications”, IEEE Transactions on Electron Devices, 55 (2008)
(24) Boon K. Teo, X. H. Sun, “Silicon-Based Low-Dimensional Nanomaterials and Nanodevices”, Chemical Reviews, 107 (2007) 1454-1532.
(25) X.H. Sun*, T. K. Sham*, R.A. Rosenberg and G.K. Shenoy, “One Dimensional Silicon–Cadmium Selenide Heterostructures”, Journal of Physical Chemistry C, 111(2007) 8475-8482.
(26) X. H. Sun, B. Yu, G. Ng, T. D. Ng, and M. Meyyappan, “III-VI Compound Semiconductor Indium Selenide (In2Se3) Nanowires: Synthesis and Characterization”, Applied Physics Letters, 89 (2006) 233121.
(27) X. H. Sun, S. Lam, T.K. Sham, F. Heigl, A. Jürgensen, N.B. Wong, “Synthesis and Synchrotron light induced luminescence of ZnO nanostructures: nanowires, nano-needles, nanoflowers and tubular whiskers”, Journal of Physical Chemistry B, 109 (2005), 3120-3125.
(28) X. H. Sun, N.B. Wong, C.P. Li, S.T. Lee, P.S.G. Kim, T.K. Sham, “Reductive self-assembling of Pd and Rh nanoparticles on silicon nanowire templates”, Chemistry of Materials, 16 (2004) 1143.
(29) X. H. Sun, S. D. Wang, N. B. Wong, D. D. D Ma, S. T. Lee, B. K. Teo, “FTIR Spectroscopic Studies of the Stabilities and Reactivities of Hydrogen-Terminated Surfaces of Silicon Nanowires”, Inorganic Chemistry, 42 (2003) 2398.
(30) X. H. Sun, C.P. Li, N.B. Wong, C.S. Lee, S.T. Lee, B.K. Teo, “Templating Effect of Hydrogen-Passivated Silicon Nanowires in the Production of Hydrocarbon Nanotubes and Nanoonions via Sonochemical Reactions with Common Organic Solvents under Ambient Conditions”, Journal of the American Chemical Society, 124 (2002) 14856.
(31) X. H. Sun, C.P. Li, W. K. Wong, N.B. Wong, C.S. Lee, S.T. Lee, B.K. Teo, “Formation of Silicon Carbide Nanotubes and Nanowires via Disproportionation Reaction of Silicon Monoxide with Carbon Nanotubes”, Journal of the American Chemical Society, 124 (2002) 14464.
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