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师资名录
院士
教授
资深教授
副教授

司廷

中国科学技术大学近代力学系

中国科学技术大学生物医学工程中心

  • 电话: 0551-63606847

  •  Email: tsi@ustc.edu.cn

  • 主页:http://staff.ustc.edu.cn/~tsi


个人简介:

司廷,国家“优青”入选者。2000年考入中国科学技术大学,2004年获理论与应用力学学士学位,2009年获流体力学博士学位,是中科院院长奖、郭永怀奖、安徽省优秀毕业生等获得者。之后从事博士后研究工作,2012年引进为中国科学技术大学特任副教授,2017年入选国家“优青”,曾于2012年及2014-2016年在美国俄亥俄州立大学做访问教授。主要从事微纳尺度流动、界面不稳定性和生物医学工程等方面的基础、应用基础以及应用开发研究,已主持4项国家自然科学基金项目,获国家专利10余项,部分成果正在产业化。先后在《Physical Review Letters》、《Journal of Fluid Mechanics》、《Physics of Fluids》、《Applied Physics Letters》、《Physical Review E》、《Lab on s Chip》等发表60余篇重要期刊论文,受邀撰写《力学进展》综述2篇等。是中国力学学会微纳尺度流动专业组委员,中国光学学会生物医学光子学专业委员会青年委员,国际期刊BMC Cancer副编辑,实验流体力学、空气动力学学报等青年编委。


教育经历:

  •  2000.9~2004.7中国科学技术大学近代力学系,理论与应用力学学士

  •  2004.9~2009.6中国科学技术大学近代力学系,流体力学 博士

工作经历:

  •  2009.6~2012.2中国科学技术大学,博士后

  •  2012.3~2012.8美国The Ohio State University,访问学者

  •  2014.8~2016.4美国The Ohio State University,访问教授

  •  2012.2~至今  中国科学技术大学近代力学系,特任副教授、副教授,国家“优青”

研究兴趣:

主要从事微纳尺度流动界面不稳定性、生物医学工程等方面的基础和应用基础科学研究,具体包括:

  • 多介质微流体技术的基础和应用研究。利用流动聚焦、电雾化、电纺丝、微流控器件等多介质微流体技术制备复合微纳胶囊,一方面开展多介质微流体的理论建模、数值模拟和实验验证,另一方面开展微纳胶囊、液滴、颗粒的开发和应用

  • 流体力学界面不稳定性的基础研究。开发圆弧形汇聚激波产生技术、初始扰动界面生成技术以及流场观测技术,开展激波和界面的相互作用研究,实验与数值模拟以及理论相结合

  • 旋流卷吸技术基础和转化研究。利用旋转流体能够产生强大抽吸力的原理开发旋流卷吸技术,在抽排、分选、输运、离心、净化等工农业领域有应用前景,实现零接触、节能减排、环保等

  • 其他流体力学相关基础和应用问题研究。


代表性论文:

  • Measurement of a Richtmyer-Meshkov instability at an air-SF6 interface in a semiannular shock tube. Physical Review Letters, 119: 014501, 2017.

  • On the interaction of a planar shock with a three-dimensional light gas cylinder. Journal of Fluid Mechanics, 828: 289-317. 2017.

  • Experimental study on a sinusoidal air/SF6 interface accelerated by a cylindrically converging shock. Journal of Fluid Mechanics, 826: 819-829. 2017.

  • The Richtmyer-Meshkov instability of a ‘V’ shaped air/SF6 interface. Journal of Fluid Mechanics, 802: 186-202, 2016.

  • On the interaction of a planar shock with an SF6 polygon. Journal of Fluid Mechanics, 773: 366-394, 2015.

  • Experimental investigation of cylindrical converging shock waves interacting with a polygonal heavy gas cylinder. Journal of Fluid Mechanics, 784: 225-251, 2015.

  • On the interaction of a planar shock with a light polygonal interface. Journal of Fluid Mechanics, 757: 800-816, 2014.

  • The Richtmyer-Meshkov instability of a three-dimensional air/SF6 interface with a minimum-surface feature. Journal of Fluid Mechanics (Rapids), 722(R2): 1-11, 2013.

  • Modes in flow focusing and instability of coaxial liquid-gas jets. Journal of Fluid Mechanics, 629: 1-23, 2009.

  • Manipulation of three-dimensional Richtmyer-Meshkov instability by initial interfacial principal curvatures. Physics of Fluids, 29: 032106, 2017.

  • Reflection of cylindrical converging shock wave at an air/helium gaseous interface. Physics of Fluids, 29: 016102, 2017.

  • Interaction of cylindrically converging diffracted shock with uniform interface. Physics of Fluids, 29: 086101, 2017.

  • The Richtmyer-Meshkov instability of a ‘V’ shaped air/helium interface subjected to a weak shock. Physics of Fluids, 28: 082104, 2016.

  • Reflection of cylindrical converging shock wave over a plane wedge. Physics of Fluids, 28: 086101, 2016.

  • A semi-annular shock tube for studying cylindrically converging Richtmyer-Meshkov instability. Physics of Fluids (Letter), 27: 091702, 2015.

  • Temporal instability of coflowing liquid-gas jets under an electric field. Physics of Fluids, 26: 054101, 2014.

  • Experimental investigation of reshocked spherical gas interfaces. Physics of Fluids, 24: 054101, 2012.

  • Parametric study of cylindrical converging shock waves generated based on shock dynamics theory. Physics of Fluids, 24: 026101, 2012.

  • On the evolution of spherical gas interfaces accelerated by a planar shock wave. Physics of Fluids, 23: 084104, 2011.

  • Spatial instability of coflowing liquid-gas jets in capillary flow focusing. Physics of Fluids, 22: 112105, 2010.  

  • Multiplex coaxial flow focusing for producing multicompartment Janus microcapsules with tunable material compositions and structural characteristics. Lab on a Chip, 17: 3168-3175, 2017.

  • Microencapsulation of indocyanine green for potential applications in image-guided drug delivery. Lab on a Chip (Communications), 15: 646-649, 2015.

  • Steady cone-jet mode in compound-fluidic electro-flow focusing for fabricating multicompartment microcapsules. Applied Physics Letters(Cover paper), 108: 021601, 2016.

  • Optical droplet vaporization of nanoparticle-loaded stimuli-responsive microbubbles. Applied Physics Letters, 108: 111109, 2016.

  • Principal curvature effects on the early evolution of three-dimensional single-mode Richtmyer-Meshkov instabilities. Physical Review E, 93: 023110, 2016.

  • Richtmyer-Meshkov instability of a three-dimensional SF6-air interface with a minimum-surface feature. Physical Review E, 93: 013101, 2016.

  • Ultrasound mediated delivery of oxygen and LLL12 loaded stimuli responsive microdroplets for the treatment of hypoxic cancer cells. Scientific Reports, 7: 44908, 2017.

  • Microfluidic fabrication of stimuli-responsive microdroplets for acoustic and optical droplet vaporizations. Journal of Materials Chemistry B, 4: 2723-2730, 2016.

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