基本信息
胡国庆 男 博导 力学研究所
电子邮件:guoqing.hu@imech.ac.cn
通信地址:中国科学院力学研究所非线性力学国家重点实验室 
邮政编码: 100190
主页:http://sourcedb.imech.cas.cn/zw/rck0/zgjzj/fxxlx/201211/t20121129_3693658.html

招生信息

研究领域:微纳米流体力学、纳米材料生物效应、生物分子/颗粒/细胞/液滴输运及操控、微纳流控器件设计

2017年度招收2名硕博连读研究生,欢迎联系!
     

招生专业
080103-流体力学
招生方向
流体力学

教育背景

   
学历
-- 研究生
学位
-- 博士

工作经历

2000.4-2001.8 以色列Ben-Gurion University of Negev     Postdoc

2001.9-2002.9 英国University of Bristol                            Postdoc

2002.10-2004.3 加拿大国家研究院           Government Laboratory Visiting Scholar

2004.4-2006.2 加拿大University of Toronto                      Research Fellow

2006.3-2007.8 美国Vanderbilit University                         Senior Research Associate

2007.11-目前 中国科学院力学研究所                                研究员

出版信息

期刊论文

1. Zhang, L.; Sun, J.; Wang, Y.; Wang, J.; Shi, X. & Hu, G. A non-specific organelle-targeting strategy with core-shell nanoparticles of varied lipid components/ratios. Analytical Chemistry (2016, in press)

2. Xue, C.; Chen, X.; Liu, C. & Hu, G. Lateral migration of dual droplet trains in a double spiral microchannel. Science China Physics, Mechanics & Astronomy, 59(7), 1-10 (2016)

3. Xue, C.; Zheng, X.; Chen, K.; Tian, Y. & Hu, G. Probing non-Gaussianity in confined diffusion of nanoparticles. The Journal of Physical Chemistry Letters, 7, 514-519 (2016)

4. Liu, C.; Xue, C.; Sun, J. & Hu, G. A generalized formula for inertial lift on a sphere in microchannels. Lab on a Chip, 16, 884-892 (2016)

5. Hu, Q.; Jiao, B.; Shi, X.; Valle, R.; Zuo, Y. & Hu, G. Effects of graphene oxide nanosheets on ultrastructure and biophysical properties of pulmonary surfactant film. Nanoscale, 7, 18025-18029 (2015) 

6. Song, K., Hu, G., Hu X., Zhong, R. & Lin, B. Encoding and controlling of two droplet trains in a microfluidic network with the loop-like structure. Microfluidics and Nanofluidics, 19, 1363-1375 (2015) 

7. Qian, Y., Zhang, J., Hu, Q., Xu, M., Chen, Y., Hu, G., Zhao, M. & Liu, S. Silver nanoparticles-induced hemoglobin decrease alteration of histone 3 methylation status. Biomaterials, 70, 12-22 (2015)  

8. Chen, X., Song, Y., Li, D. & Hu, G. Deformation and interaction of droplet pairs in a microchannel under ac electric fields. Physical Review Applied, 4, 024005 (2015) 

9. Feng, Q., Zhang, L., Liu, C., Li, X., Hu, G., Sun, J. & Jiang, X. Microfluidic based high throughut synthesis of lipid-polymer hybrid nanoparticles with tunable diameters. Biomicrofluidics, 9, 052604 (2015) 

10. Liu, C., Xue, C., Chen, X., Shan, L., Tian, Y. & Hu, G. Size-based separation of particles and cells utilizing viscoelastic effects in straight microchannels. Analytical Chemistry, 87, 6041-6048 (2015) 

11. Chen, K., Shan, L., He, S., Hu, G., Meng, Y. & Tian, Y. Biphasic resistive pulses and ion concentration modulation during particle translocation through cylindrical nanopores. Journal of Physical Chemistry C, 119, 8329-8335 (2015)   

12. 陈晓东,胡国庆. 微流控器件中的多相流动. 力学进展, 201503 (2015)  

13. Liu, C., Hu, G., Jiang, X. & Sun, J. Inertial focusing of spherical particles in rectangular microchannels over a wide range of Reynolds numbers. Lab on a Chip, 15, 1168-1177 (2015)  

14. Chen, X., Xue, C., Zhang, L., Hu, G., Jiang, X. & Sun, J. Inertial migration of deformable droplets in a microchannel. Physics of Fluids, 26, 112003 (2014) 

15. Wang, J., Zhang, L., Xue, J. & Hu, G. Ion diffussion coefficient measurements in nanochannels at various concentrations. Biomicrofluidics, 8, 024118 (2014)  

16 Wang, J., Chen, W., Sun, J., Liu, C., Yin, Q., Zhang, L., Xiangyu, Y., Shi, X., Hu, G. & Jiang, X. A Microfluidic tubing method and its application to controlled synthesis of polymeric nanoparticles. Lab on a Chip, 14, 1673-1677 (2014)  

17. Yu, W., Qu, H., Hu, G., Zhang, Q., Song, K., Guan, H., Liu, T. & Qin, J. A microfluidic-based multi-shear device for investigating the effects of low fluid-induced stresses on osteoblasts. PLoS ONE, 9, e89966 (2014)   

18. Wang, J., Ma, J., Ni, Z., Zhang, L. & Hu, G. Effects of access resistance on the resistive-pulse caused by translocating of a nanoparticle through a nanopore. RSC Advances, 4(15), 7601-7610 (2014)  

19. Kale, A., Patel, S., Qian, S., Hu, G. & Xuan, X. Joule heating effects on reservoir‐based dielectrophoresis. Electrophoresis, 35, 721-727 (2014)  

20. Hu, G., Jiao, B., Shi, X., Valle, R. P., Fan, Q. & Zuo, Y. Y. Physicochemical properties of nanoparticles regulate translocation across pulmonary surfactant monolayer and formation of lipoprotein corona. ACS nano, 7(12), 10525-10533 (2013)   

21. Kale, A., Patel, S., Hu, G. & Xuan, X. Numercial modeling of Joule heating effects in insulator-based dielectrophoresis microdevices. Electrophoresis, 34, 674-683 (2013)   

22. Sun, J., Xianyu, Y., Li, M., Liu, W., Zhang, L., Liu, D., Liu, C., Hu, G. & Jiang, X. A microfluidic origami chip for synthesis of functionalized polymeric nanoparticles. Nanoscale, 5(12), 5262-5265 (2013)  

23. Sun, J., Liu, C., Li, M., Wang, J., Xianyu, Y., Hu, G., & Jiang, X. Size-based hydrodynamic rare tumor cell separation in curved microfluidic channels.  Biomicrofluidics, 7, 011802 (2013)  

24. Sun, J., Li, M., Liu, C, Zhang Y., Liu, D., Liu, W., Hu, G. & Jiang, X. Double spiral microchannel for label-free tumor cell separation and enrichment. Lab on a Chip, 12, 3952-3960 (2012)  

25. Zhu, J., Hu, G. & Xuan, X. Electrokinetic particle entry into microchannels. Electrophoresis, 33, 916-922 (2012)  

26. Zhu, J., Sridharan, S., Hu, G. & Xuan, X. Joule heating effects on electrokinetic focusing and trapping of particles in constriction microchannels. Journal of Micromechanics and Microengineering, 22(7), 075011 (2012) 

27. Lin, X., Hu, G., Chen, Q., Niu, L., Ostendorf, A. & Sun, H. A light-driven turbine-like micro-rotor and study on its light-to-mechanical power conversion efficiency. Applied Physics Letters, 101(11), 113901 (2012)  

28. Song, K., Zhang, L. & Hu, G. Modeling of droplet traffic in interconnected microfluidic ladder devices. Electrophoresis, 33, 411-418 (2012)   

29. Wang, L., Sun, L., Wang, C., Chen, L., Cao, L., Hu, G., Xue, J. & Wang, Y. Nanofluidic pulser based on polymer conical nanopores. Journal of Physical Chemistry C, 115, 22736-22741 (2011)  

30. Sridharan, S., Zhu, J., Hu, G. & Xuan, X. Joule heating effects on electroosmotic flow in insulator-based dielectrophoresis. Electrophoresis, 32, 2274-2281 (2011)  

31. Zhu, J., Tzeng, T.-R. J., Hu, G. & Xuan, X. DC dielectrophoretic focusing of particles in a serpentine microchannel. Microfluidics and Nanofluidics, 7, 751-756 (2009)  

32. Sun, J., Vajandar, S. K., Xu, D., Kang, Y., Hu, G., Li, D. & Li, D. Experimental characterization of electrical current leakage in poly(dimethylsiloxane) microfluidic devices. Microfluidics and Nanofluidics, 6, 589-598 (2009)  

33. Hu, G. & Li, D. Microfluidic effects of transporting signaling components in cell coculture chips. Microfluidics and Nanofluidics, 6, 99-107 (2009)  

34. Hu, G., Quaranta, V. & Li, D. Modeling of effects of nutrient gradients on cell proliferation in microfluidic bioreactor. Biotechnology Progress, 23, 1347-1354 (2007).  

35. Hu, G. & Li, D. Three-dimensional modeling of transport of nutrients for multicellular tumor spheroid culture in a microchannel. Biomedical Microdevices, 9, 315-323 (2007).  

36. Hu, G. & Li, D. Multiscale phenomena in microfluidics and nanofluidics. Chemical Engineering Science, 62, 3443-3454 (2007).  

37. Hu, G., Gao, Y. & Li, D. Modeling micropatterned antigen-antibody binding kinetics in a microfluidic chip. Biosensors & Bioelectronics, 22, 1403-1409, (2007)  

38. Xuan, X., Hu, G. & Li, D. Joule heating effects on separation efficiency in capillary zone electrophoresis with an initial voltage ramp. Electrophoresis, 27, 3171-3180 (2006).  

39. Xiang, Q., Hu, G., Gao, Y. & Li, D. Miniaturized immunoassay microfluidic system with electrokinetic control. Biosensors & Bioelectronics, 21, 2006-2009 (2006)  

40. Hu, G., Xiang, Q., Fu, R., Xu, B., Venditti, R. & Li, D. Electrokinetically controlled real-time polymerase chain reaction in microchannel using Joule heating effect. Analytica Chimica Acta,  557, 146-151 (2006)  

41. Hu, G. , Lee, J. S. H. & Li, D. A microfluidic fluorous solid-phase extraction chip for purification of amino acids. Journal of Colloid and Interface Science, 301, 697-702 (2006).  

42. Hu, G. , Gao, Y., Sherman, P. M. & Li, D. A microfluidic chip for heterogeneous immunoassay using electrokinetical control. Microfluidics and Nanofluidics, 1, 346-355 (2005)  

43. Gao, Y., Lin, F. Y., Hu, G., Sherman, P. M. & Li, D. Development of a novel electrokinetically driven microfluidic immunoassay for the detection of Helicobacter pylori. Analytica Chimica Acta, 543, 109-116 (2005)   

44. Gao, Y., Hu, G., Lin, F.Y.H., Sherman, P. M. & Li, D. An electrokinetically-controlled immunoassay for simultaneous detection of multiple microbial antigens. Biomedical Microdevices, 7, 301-312 (2005)  

45. Igra, O., Hu, G., Falcovitz, J. & Wang, B. Y. Shock wave reflection from a wedge in a dusty gas. International Journal of Multiphase Flow, 30, 1139-1169 (2004)  

46. Igra, O., Hu, G., Falcovitz, J. & Heilig, W. Blast waive reflection from wedges. Journal of Fluids Engineering-Transactions of the ASME, 125, 510-519 (2003)  

47. Igra, O., Wu, X., Hu, G.. & Falcovitz, J. Shock wave propagation into a dust-gas suspension inside a double-bend conduit. Journal of Fluids Engineering-Transactions of the ASME, 124, 483-491 (2002)  


书籍及章节 

1. Feng, G., Hu, G., Qiao, R. & Aluru, N. R. 2015. Structure of the electrical double layers: Insight from continuum and atomistic simulations, chapter in Computational Bioengineering. CRC Press. 

2. 李战华,吴健康,胡国庆,胡国辉. 2012. 微流控芯片中的流体流动. 中国科学出版社. 

3. Li, D., Hu, G. 2008. Nanoscale biosensors, in Encyclopedia of Micro- and Nanofluidics. Springer.  

4. Hu, G., Li, D. 2008. Multiscale modeling and numerical simulations, in Encyclopedia of Micro- and Nanofluidics. Springer  


指导学生

已指导学生

焦豹  博士研究生  080103-流体力学  

宋奎  博士研究生  080103-流体力学  

王俊荣  博士研究生  080103-流体力学  

现指导学生

胡青林  博士研究生  080103-流体力学  

刘超  博士研究生  080103-流体力学  

贺思远  硕士研究生  080103-流体力学  

白轩  硕士研究生  080102-固体力学  

薛春东  博士研究生  080103-流体力学