太阳成集团tyc4633
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吴春梅

职称:教授

联系方式:chunmeiwu@cqu.edu.cn

主要从事:​从事有关传热传质、界面现象及能量传输、非平衡热力学理论及应用、流动稳定性等方面的教学和科研工
  • 个人简介
  • 教育经历
  • 研究方向
  • 本科生及公司产品
  • 科研项目
  • 代表性论文

吴春梅,1987年生,太阳成集团tyc4633教授,博(硕)士生导师。2008年保送太阳成集团硕博连读,2010-2012年加拿大多伦多大学博士联合培养,在2013年6月获博士学位。2013年至2015年在多伦多大学从事博士后研究工作。多年来一直从事有关传热传质、界面现象及能量传输、非平衡热力学理论及应用、流动稳定性等方面的教学和科研工作,主讲本科《传热学》、研究生《高等传热学》等课程,主持国家自然科学基金面上项目,青年项目、重点项目子课题、博士后特别资助项目、重庆市自然科学面上项目,重庆市留学人员创新资助项目等,参研多项国家自然科学基金面上项目。《工业加热》期刊编委,International Journal of Heat and Mass Transfer,Physics of Fluid等期刊审稿人,国家自然科学基金通讯评审专家,载人空间站微重力流体物理领域项目通讯评审专家,曾获黄尚廉院士青年创新奖,中国工程热物理年会传热传质分会“王补宣青年论文奖”一等奖等多项奖励。近年来在国内外重要刊物上发表研究论文60余篇。

2010.09-2012.10    加拿大多伦多大学     博士联合培养 

2008.09-2013.07    太阳成集团             工学博士 

2004.09-2008.07    太阳成集团             工学学士 

2020.09-至今     太阳成集团tyc4633  教授 /博(硕)士生导师 

2015.09-2020.8     太阳成集团tyc4633  副教授 /博(硕)士生导师 

2013.10-2015.04    加拿大多伦多大学             博士后 

2013.07-2015.08    太阳成集团tyc4633   讲师

界面现象及能量传输

传热传质及节能技术

非平衡热力学理论及应用

流动稳定性及失稳机理研究

吸附机理研究

 


国家自然科学基金面上项目,主持

国家自然科学基金青年项目,主持

国家自然科学基金重点项目子项,主持

重庆市自然科学基金面上项目,主持

重庆市留学回国人员创新创业项目,主持

重庆市留()渝博士后择优资助项目,主持

中国博士后基金特别资助项目,主持

太阳成集团前沿交叉学科培育专项,主持

 


[1]     Wu CM, Wei X., Li YR, Investigation on the mechanisms of cluster formation  and transition from adsorption to condensation, International Journal of Heat and Mass Transfer, 2021, 171:121096

[2]     Wei X., Wu CM, Li YR, Molecular insight into the formation of adsorption clusters based on the zeta isotherm, Physical Chemistry Chemical Physics, 2020, 22, 10123-10131

[3]     Wu CM, Chen J.H., Li YR, Mixed oscillation flow of binary fluid with minus one capillary ratio in the czochralski crystal growth model, Crystals, 2020(3), 213.

[4]     Wu CM, Chen J.H., Yuan B., Li YR, Bifurcations and pattern evolutions of thermo-solutocapillary flow in rotating cylinder with a top disk, Physics of Fluids, 31:094103, 2019.

[5]     Chen JC, Wu CM, Li YR, Yu JJ, Capillary ratio dependence of thermal-solutal capillary convection in a shallow annular pool with radial temperature and concentration gradients, International Journal of Thermal Sciences, 139:15-24, 2019.

[6]     Wu CM, Luo J.Q., Yu J.J., Li Y. R., Thermocapillary convection of a binary mixture with the Soret effect in a shallow annular pool heated from belowFluid Dynamics Research, 51: 065501, 2019

[7]     Wu CM, Yuan B, Li YR, Flow Instabilities of Coupled Rotation and Thermal-Solutal Capillary Convection of Binary Mixture in Czochralski Configuration, Crystals, 9:72, 2019.

[8]     Shen T, Wu CM, Li YR, Numerical simulation on effect of rotation on thermal convection in a shallow model czochralski configuration with a heated bottom, Crystal Research and Technology, 52(9):1700268, 2018.

[9]     Zhang L, Luo JQ, Wu CM, Yu JJ, Li YR, Thermocapillary convection in a binary mixture with moderate Prandtl number in a shallow annular pool, Microgravity Science and Technology, 30(1-2):33-42, 2018.

[10]  Ye S, Wu CM, Zhang L, Li YR, Liu QS, Evolution of thermal patterns during steady state evaporation of sessile droplets, Experiemtnal Thermal and Fluid Science, 98: 712-718, 2018.

[11]  Chen JC, Wu CM, Li YR, Yu JJ, Effect of capillary ratio on thermal-solutal capillary-buoyancy convection in a shallow annular pool with radial temperature and concentration gradients, International Journal of Heat and Mass Transfer, 109: 367-377, 2017.

[12]  Yu JJ, Wu CM, Li YR, Chen JC, Thermal-solutal capillary-buoyancy flow of a low Prandtl number binary mixture with a -1 capillary ratio in an annular pool, Physics of Fluids, 28(8):084102, 2016.

[13]  Shen T, Wu CM, Zhang L, Li YR, Experimental investigation on effects of crystal and crucible rotation on thermal convection in a model Czochralski configuration. Journal of Crystal Growth, 438:55-62, 2016.

[14]  Shen T, Wu CM, Li, Li YR, Experimental investigation on the effect of crystal and crucible rotation on thermocapillary convection in a Czochralski configuration, International Journal of Thermal Sciences, 104:20-28, 2016.

[15]  Wu CM, Zandavi SH, Ward CA, Prediction of the wetting condition from the Zeta adsorption isotherm, Physical Chemistry Chemical Physics, 16(46):25564-72, 2014.

[16]  Wu CM, Liao RJ, Rotating and thermocapillary-buoyancy-driven flow in a cylindrical enclosure with a partly free surface, Physics of Fluids, 26:104105, 2014.

[17]  Wu CM, Ran DF, Liao RJ, Flow pattern transition driven by the combined Marangoni effect and rotation of crucible and crystal in a Czochralski configuration, International Journal of Thermal Sciences, 86:394-407, 2014.