石万元：博士、教授、博士生导师

2006年获日本九州大学工学博士学位，分别在北海道大学、东北大学（日本）从事博士后研究工作。多年来一直从事传热学、非平衡热力学的教学和科研工作，主持和参与了多项国家自然科学基金项目、科技部“973”计划项目、国家自然科学基金重点项目和其它省部级项目的研究。已在国际国内期刊发表学术论文近40篇，其中SCI论文近30篇，申请及授权发明专利3项，参加编写了《传热分析与计算》教材1部。担任国家自然科学基金项目函评专家、《力学研究》期刊编委，International Journal of Hydrogen Energy、International Journal of Heat and Mass Transfer、Physics of Fluids、Microgravity Science and Technology、工程热物理学报等多个国际国内学术期刊审稿人。

联系电话：13983719902

Email: shiwy@cqu.edu.cn

主要研究方向：

热对流及失稳现象；

液体蒸发过程传热传质规律；

气液两相流及复杂界面问题数值模拟；

电磁悬浮技术及悬浮液滴稳定性问题；

非平衡热力学稳定性理论及应用。

主讲课程：

本科生：《传热学》

研究生：《非平衡热力学》

代表性论文：

[1]     H-M Li, W-Y Shi. Thermocapillary convection in a differentially heated two-layer annular system with and without rotation. Int J Heat Mass Transfer, 2017, 105: 684-689.

[2]     L Feng, W-Y Shi. The influence of Marangoni effect on flow and deformation of an electromagnetically levitated molten droplet under static magnetic fields. Int J Heat Mass Transfer, 2016, 101: 629-636.

[3]     W-Y Shi, S-M Rong, L Feng. Marangoni convection instabilities induced by evaporation of liquid layer in an open rectangular pool. Microgravity Science and Technology, 2016, DOI 10.1007/s12217-016-9528-3.

[4]     X-H Tian, W-Y Shi, T Tang, L Feng. Influence of vertical static magnetic field on behavior of rising single bubble in a conductive fluid. ISIJ International, 2016, 56: 195-204.

[5]     L Feng, W-Y Shi. Influence of coil angle arrangement on dynamic deformation and stability of molten droplet in electromagnetic levitation system. ISIJ International, 2016, 56: 50-56.

[6]     L Feng, W-Y Shi. The influence of eddy effect of coils on flow and temperature fields of molten droplet in electromagnetic levitation device. Metallurgical and Materials Transactions B, 2015, 46: 1895-1901.

[7]     W.Y. Shi, Y.-R. Li, M.K. Ermakov, N. Imaishi. Stability of thermocapillary convection in rotating shallow annular pool of silicon melt. Microgravity Science and Technology, 2010, 22: 315-320.

[8]     W.Y. Shi, G. Y. Li, X. Liu, Y.-R. Li, L. Peng, N. Imaishi. Thermocapillary convection and buoyant-thermocapillary convection in the annular pools of silicon melt and silicone oil. J. Superconductivity and Novel Magnetism, 2010, 23: 1169-1172.

[9]     W.Y. Shi, X. Liu, G. Y., Li Y.-R. Li, L. Peng, M. K. Ermakov, N. Imaishi. Thermocapillary convection instability in shallow annular pools by linear stability analysis. J. Superconductivity and Novel Magnetism, 2010, 23: 1185-1188.

[10]  W.Y. Shi, M. K. Ermakov, Y.-R. Li, L. Peng, N. Imaishi. Influence of buoyancy force on thermocapillary convection instability in the differentially heated annular pools of silicon melt. Microgravity Science and Technology, 2009, 21: S289–S297.

[11]  W.Y. Shi, E. Kurihara, N. Oshima. Effect of capillary pressure on liquid water removal in a cathode gas diffusion layer of polymer electrolyte fuel cell. J. Power Sources, 2008, 182:112-118.

[12]  W.Y. Shi, N. Imaishi. Thermocapillary convection in a shallow annular pool heated from inner wall. Microgravity Science and Technology, 2007, XIX: 104-105.

[13]  W.Y. Shi, N. Imaishi. Hydrothermal waves in rotating annular pools of silicon melt. Microgravity Science and Technology, 2007, XIX: 159-160.

[14]  W.Y. Shi, N. Imaishi. Experimental investigation on hydrothermal wave in a shallow annular pool. Microgravity Science and Technology, 2007, XIX: 161-162.

[15]  L. Peng, Y.-R. Li, W.-Y. Shi, N. Imaishi. Three-dimensional thermocapillary-buoyancy flow of silicone oil in a differentially heated annular pool. Int. J. Heat Mass Transfer, 2007, 50: 872-880.

[16]  W.Y. Shi, M. K. Ermarkov, N. Imaishi. Effect of pool rotation on thermocapillary convection in shallow annular pool of silicone oil. J. Crystal Growth, 2006, 294: 474-485.

[17]  W.Y. Shi, N. Imaishi. Hydrothermal waves in differentially heated shallow annular pools of silicone oil, J. Crystal Growth, 2006, 290: 280-291.

[18]  唐甜，石万元. 固定接触角蒸发液滴内Marangoni对流数值模拟. 工程热物理学报，2017，已接收.

[19]  陈贤琴，石万元，李翰明. 环形池内反常热毛细对流及稳定性线性稳定性分析. 工程热物理学报，2017，已接收.

[20]  宋其晖，石万元. 横向静磁场对电磁悬浮液滴稳定性的影响. 物理学报，2014，63：248504.

[21]  李翰明, 石万元, 周涛, 王瑜. 环形池内双层流体热毛细对流不稳定现象实验研究, 工程热物理学报, 2014, 35: 762-765.

[22]  石万元，王瑜. 系统旋转对浅环形池内硅油热毛细对流影响的实验研究. 工程热物理学报, 2013，34：702-705.

[23]  石万元，李建英，王瑜，李友荣. 数值分析环形池硅熔体旋转-热毛细对流及其稳定性. 工程热物理学报，2012，33：856-860.

[24]  石万元，张凤超，田小红，等. 相场法模拟悬浮熔融硅液滴内部对流及自由界面变形现象. 西南交通大学学报，2012，47：692-697.

[25]  石万元，李友荣，彭岚. Pr数对环形浅液池热毛细对流的影响. 工程热物理学报， 2011，32：250-254.

[26]  石万元，李友荣，彭岚，曾丹苓，今石宣之. 环形浅液池内热流体波的本质特征. 计算力学学报, 2009，26: 59-65.

[27]  石万元，李友荣，今石宣之. 三维数值模拟内环加热的环形硅油液层内的热毛细对流. 力学学报, 2008，4: 433-440.

[28]  石万元，李友荣， M. K. Ermakov，今石宣之. 环形液层内热毛细对流的线性稳定性分析. 工程热物理学报, 2008, 29: 1218-1220.

[29]  石万元，李友荣，曾丹苓，今石宣之. 环形浅液层内热流体波的可视化实验研究. 工程热物理学报, 2007, 28: 101-104.