主要学术成果(论文、专利、专著、译著等) |
期刊论文: 1. Pang Y, Du Y, Wang J, Liu Z M. Generation of single/double Janus emulsion droplets in co-flowing microtube[J]. International Journal of Multiphase Flow, 2019, 111: 199-207. 2. Wang X, Liu Z M, Pang Y. Breakup dynamics of droplets in an asymmetric bifurcation by μPIV and theoretical investigations[J]. Chemical Engineering Science, 2019, 197: 258-268. 3. Wang X, Liu Z M, Pang Y. Collision characteristics of droplet pairs with the presence of arriving distance differences[J]. Journal of Industrial and Engineering Chemistry, 2019, 69: 225-232. 4. Liu Z M, Li M Q, Pang Y, et al. Flow characteristics inside droplets moving in a curved microchannel with rectangular section[J]. Physics of Fluids, 2019. (Doi:10.1063/1.5080373) 5. Liu Z M, Du Y, Pang Y. Generation of Water-In-Oil-In-Water (W/O/W) Double Emulsions by Microfluidics[J]. Chinese Journal of Analytical Chemistry, 2018, 46(3): 324-330. 6. Zhang L X, Liu Z M, Pang Y, et al. Trapping a moving droplet train by bubble guidance in microfluidic networks[J]. RSC Advances, 2018, 8(16): 8787-8794. 7. Liu Z M, Zhao J, Pang Y, et al. Generation of droplets in the T-junction with a constriction microchannel[J]. Microfluidics and Nanofluidics, 2018, 22(11): 124. 8. Wang X, Liu Z M, Pang Y. Droplet breakup in an asymmetric bifurcation with two angled branches[J]. Chemical Engineering Science, 2018, 188: 11-17. 9. Liu Z M, Zhang L X, Pang Y, et al. Micro-PIV investigation of the internal flow transitions inside droplets traveling in a rectangular microchannel[J]. Microfluidics and Nanofluidics, 2017, 21(12): 180. 10. Liu Z M, Yang Y, Du Y, Pang Y. Advances in Droplet-Based Microfluidic Technology and Its Applications[J]. Chinese Journal of Analytical Chemistry, 2017, 45(2): 282-296. 11. Wang X, Liu Z M, Pang Y. Concentration gradient generation methods based on microfluidic systems[J]. RSC Adv. 2017, 7(48): 29966-29984. 12. Pang Y, Liu Z M, Zhao F W. Downstream pressure and elastic wall reflection of droplet flow in a T-junction microchannel[J]. Acta Mechanica Sinica, 2016, 32(4): 579-587. 13. Liu Z M, Wang X, Cao R T, Pang Y. Droplet coalescence at microchannel intersection chambers with different shapes[J]. Soft Matter, 2016, 12(26): 5797-5807. 14. Liu Z M, Pang Y. Effect of the size and pressure on the modified viscosity of water in microchannels[J]. Acta Mechanica Sinica, 2015, 31(1): 45-52. 15. Liu Z M, Cao R T, Pang Y, et al. The influence of channel intersection angle on droplets coalescence process[J]. Experiments in Fluids, 2015, 56(2): 24. 16. Pang Y, Kim H, Liu Z M, et al. A soft microchannel decreases polydispersity of droplet generation[J]. Lab Chip, 2014, 14(20): 4029-4034. 17. 刘赵淼, 王文凯, 逄燕. 扩展腔对方波型微混合器混合性能的影响研究[J]. 力学学报, 2018, 50(2): 254-262. 18. 刘赵淼, 逄燕. 不同压力差下微通道尺寸和表面粗糙度对摩擦系数的影响[J]. 工程力学, 2012, 29(5): 200-205. 19. 刘赵淼, 逄燕. 几何尺寸对矩形微通道液体流动和传热性能的影响[J]. 机械工程学报, 2012, 48(16): 139-145. 国家发明专利: 1. 刘赵淼,王翔, 逄燕. 一种利用蜡笔手绘的纸芯片制作方法, 2017.5.10, 中国, ZL201610889294.7 2. 刘赵淼, 王翔, 逄燕. 通道上下两壁面指定位置可变形的微流控芯片, 2017.2.15, 中国, ZL201610836147.3 3. 刘赵淼, 王翔, 逄燕. 一种测量壁面可变形通道中压力变化的微流控芯片, 2017.2.1, 中国, ZL201610757833.1 4. 刘赵淼,王翔,逄燕. 通道侧壁面指定位置可动的微流控芯片2015.10.28,中国, ZL201510712606.2 5. 刘赵淼,逄燕,王翔. 一种基于支路结构的微液滴控制芯片2015.9.29中国, ZL201510629645.6 6. 刘赵淼,逄燕,王翔. 基于微通道的下壁面指定位置可动的微流控芯片2015.7.1, 中国, ZL201510379947.2 7. 刘赵淼,王翔,逄燕. 下壁面内凹的微通道的制作方法2015.07.01 中国, ZL201510379969.9 8. 刘赵淼,逄燕,王翔. 单面微米级薄膜微通道的制作方法2015.7.1 中国, ZL201510379966.5 9. 刘赵淼,逄燕,王翔. 利用凹槽实现下底面可动的微通道的制作方法2015.7.1, 中国, ZL201510379949.1 10. 刘赵淼,王翔,逄燕. 下壁面外凸的微通道的制作方法2015.7.1 中国ZL201510379963.1. 11. Yan Pang,Hyoungsoo Kim,Zhaomiao Liu,Howard A. Stone. Monodispersed droplet generation device by using a passive soft microchannel, 2015.02.10, 美国, 62114111 12. 刘赵淼,逄燕,曹刃拓. 基于图像灰度分析的微尺度薄膜振动频率的测量方法, 2014.08.20, 中国, ZL201410307243.X 13. 刘赵淼,逄燕,曹刃拓. 基于T形微通道的弹性壁面微流控芯片2014.08.19, 中国, ZL201410306954.5 软件著作权: 1. 刘赵淼, 徐元迪, 任彦霖, 逄燕, 赵圣伟. 粒子运动实验图像处理软件V1.0, 2019SR0032244, 2018.11.27 2. 刘赵淼, 徐元迪, 任彦霖, 逄燕, 赵圣伟, 钟希祥, 高山山. 微滴喷射实验图像处理软件V1.0, 2019SR0056677, 2018.11.27 3. 刘赵淼, 王飓, 逄燕, 李梦麒. 微流控液滴几何参数自动测量软件, 2017SR530063, 2017.7.14 4. 刘赵淼, 王飓, 逄燕. 基于Fluent架构的微流体混合强度计算软件, 2017SR273892. 2017.3.30 |