Journal papers（*为通讯作者）

 

2024年

 

71.   Zhihui ZHANG, Xian WANG*. Improving leading edge cooling through transpiration with partitioned porous injectors and a jet[J]. Applied Thermal Engineering, 2024, 238: 121987.

70.   Zhihui ZHANG, Xian WANG*. Cooling effects of the derived coolant-film layer from partitioned porous injectors for transpiration cooling[J]. International Journal of Heat and Fluid Flow , 2024, 106: 109319.

69.    XiangZhuang KONG, Hongming ZHANG, Yanxia DU, Xian WANG*, Guangming XIAO. A study of pore scale flow and conjugate heat transfer characteristics in real and Kelvin anisotropic foams. International Journal of Heat and Mass Transfer , 2024, 221: 125024. 

68.    Hongming ZHANG, Ziyuan HUANG, Xiangzhuang KONG, Xian WANG*, Guangming XIAO, Yanxia DU. Research on the thermal response characteristics of lightweight insulation structure with various shaped lattice units. Applied Thermal Engineering, 2024, 246: 123006 (1-14). 

67.  李国辉，吴小雨，王娴*。Oldroyd-B 黏弹性液滴撞击弯曲壁面的数值研究。力学学报，2024, 56(4): 1-14.

66.  孔祥壮，张超，杜雁霞，王娴*，肖光明。各向异性多孔材料流动换热特性数值研究。工程热物理学报，2024. (In publishing)

65.  陈明石，王娴*。碘离子推力器储罐性能影响因素数值研究。气体物理，2024.   DOI：10.19527/j.cnki.2096-1642.1097

 

2023年

64.  Chao ZHANG, Hui WANG, Yanxia DU, Xian WANG*, Guangming XIAO. The influence of natural convection on effective thermal conductivity of anisotropic open-cell foam. Journal of Enhanced Heat Transfer, 2023, 30(8), 141-166

63.  Chao ZHANG, Kefan WU, Xiangzhuang KONG, Xian WANG*, Guangming XIAO. The effects of interfacial thermal contact resistance between yarns and matrixes on the thermophysical property of the plain woven C/SiC composite. Applied Thermal Engineering, 2023, 229,120600（1-15）

62.   Zhihui ZHANG, Xian WANG*. Effects of blowing ratios on the near-wall flow transition and heat transfer in coupled-domain transpiration cooling[C]//AIAA AVIATION 2023 Forum. 2023: 4401 (EI, Published Online 10.2514/6.2023-4401).

61.    Xiangzhuang KONG, Hongming ZHANG, Xian WANG*. A study of flow and heat transfer characteristics in real and ideal anisotropic foams [C]//AIAA AVIATION 2023 Forum. 2023: 4401 (EI, Published Online 10.2514/6.2023-3807).

60. 张超，孔祥壮，杜雁霞，王娴*，肖光明。各向异性Kelvin泡沫胞元高径比对其流动传热特性的影响。空气动力学报，2023, 41: 1−12。

2022年

59.  Xiangcheng SUN, Chao ZHANG, Xian WANG*. A DNS investigation by LBM: Acoustic characteristics of a flow around rod-hydrofoil configuration at different angles of attack. Ocean Engineering, 2022，266, 112779 (1-12) 

58.  Zhihui ZHANG, Xiaoyu WU, Xian WANG*. Near-wall vortices and thermal simulation of coupled-domain transpiration cooling by a recursive regularized lattice Boltzmann method. Physics of Fluids , 2022, 34, 107105 (1-17)

57. Chao ZHANG, XiangZhuang KONG, Xian WANG*, Yanxia DU, Guangming XIAO*. A Predicting Model for the Effective Thermal Conductivity of Anisotropic Open-Cell Foam [J]. Energies, 2022, 15, 6091 (1-17)  

56. 王小伟，张智慧，王娴^*。结冰环境热合成双射流激励器工作特性数值研究[J]，气体物理，2022, 7(2):65-74  

2021年

55. Zhihui ZHANG, Xiangcheng SUN, Xian WANG*. Flow Structure and Heat Transfer of Transpiration Cooling by Using A LBM: the Effect of Wall Blowing and Spatially Nonuniform Injection[J]. International Communication of heat and mass transfer , 2021，127：105491 

54. 祝衔琦，孙祥程，王娴^*。迎角对扑翼运动气动性能影响的高性能数值研究[J]，空气动力学学报，2021, 39: 1-11. 

53. 谢小乐，李济源，王娴^*，鲁海峰，韩先伟。吸气式电推进系统进气道结构对进气性能影响研究[J]，航空学报，2021, 42: 125272.  

2020年

52.  Shaozhen GUO, Guangming XIAO, Yanxia DU, Xian WANG*. A Study on the Characteristics of Cascade Heat Storage Based on Series Composite Phase Change Materials[J]. Heat Transfer Research, 2020, 51(10):925-935.

51.   郭绍振，肖光明，张楠，杜雁霞，王娴*，基于复合相变材料的梯级组合蓄热特性研究[J]，制冷学报，2020, 41(3): 140-146.

 50．马奕新，张虎*，王娴，唐桂华. TCi方法测试理论假设引入测量误差数值分析[J].科学通报, 2020, 65(8):740-749.

 49．马奕新，金宇，张虎*，王娴，唐桂华. 翅片重力热管传热性能实验研究[J].化工学报, 2020, 71(2): 594-601.

2019年

48. Yanqin SHANGGUAN, Xian WANG*, Hu ZHANG, Yueming LI. LBM study on unsteady flow and heat-transfer behaviors of double-row film cooling with various row spacings[J]. International Journal of heat and mass transfer , 2019, 138 :1251-1263.

47.   夏京京，张超，王娴*，微重力下舱内混合对流传热高性能数值研究[J]，热力发电，2019, 48(8): 27-35.

2018年

46.  Xian WANG*, Yanqin SHANGGUAN, Hu ZHANG, Yueming LI. Numerical study on the near-wall characteristics of compound angled film cooling based on hybrid thermal lattice Boltzmann method, Applied Thermal Engineering , 2018, 129:1670-1681.

45.  Yanqin SHANGGUAN, Xian WANG*, Hu ZHANG, Yueming LI. Further investigation on the flow and heat transfer mechanism of single-jet film cooling based on hybrid thermal lattice Boltzmann method, Communications in Computational Physics, 2018, 23(4), 1094-1115.

44.   Haoran HU, Chao ZHANG, Xian WANG*. Numerical acoustic simulation of flow around circular cylinders based on Lattice Boltzmann method and Ffowcs Williams-Hawkings acoustic equation[J]. International Journal of Computational Materials Science and Engineering, 2018, 1850010, 1-16. (DOI: 10.1142/S2047684118500100)

43.   Hu ZHANG*, Xian WANG, Yue-Ming LI, Measuring radiative properties of silica aerogel composite from FTIR transmittance test using KBr as diluents [J]. Experimental Thermal and Fluid Science, 2018, 91: 144-154.

42.  Hu ZHANG*, Chao ZHANG, Wen-Tao JI, Xian WANG, Yue-Ming LI, Wen-Quan TAO, Experimental characterization of the thermal conductivity and microstructure of opacifier-fiber-aerogel composite [J]. Molecules,  2018, 23(9): 2198-12.

41.  张虎^*, 马奕新, 王娴, 冀文涛, 李跃明, 陶文铨. 添加物对氧化硅凝胶隔热性能影响的实验研究[J].工程热物理学报, 2018, 39(5):1039-1043.

2017年

40.  Yanqin SHANGGUAN, Xian WANG*, Hu ZHANG, Yueming LI. Analysis on the mechanism of evolutionary process of counter-rotating vortex pair in film cooling based on hybrid thermal lattice Boltzmann method, International Communication of heat and mass transfer , 2017, 87:72-83.

39. Hu ZHANG*,Wenzhen Fang,  Xian WANG, Yueming LI, Wenquan TAO, Thermal conductivity of fiber and opacifier loaded silica aerogel composite. International Journal of Heat and Mass Transfer, 2017,115(B):21-31. 

38.  Zhen LI,  Xian WANG, Yueming LI. The band gap variation of a two dimensional binary locally resonant structure in the thermal environment.  AIP Advances, 2017, 7, 015002.  doi: 10.1063/1.4973723

37.   张保雷，上官燕琴，王娴*，陈刚，李跃明。低雷诺数下横流-射流中剪切涡的实验研究[J]，航空学报，2017，38（7）：120831, DOI: 10.7527/S1000-6893.2016.0305.

 2016年

36.  Yanqin SHANGGUAN,  Xian WANG*, Yueming LI. Investigation on the mixing mechanism of single-jet film cooling with various blowing ratios based on hybrid thermal lattice Boltzmann method. International Journal of Heat and Mass Transfer, 2016, 97: 880-890.

35. Yijun CHAI, Lin CHEN, Xian WANG, Yueming LI. Study on stress development in the phase transition layer of thermal barrier coatings. Materials, 2016, 9(9): 773.

2015年

34.   Yanqin SHANGGUAN,  Xian WANG*, Yueming LI. Large-scaled simulation on the coherent vortex evolution of a jet in cross-flow based on lattice Boltzmann method. Thermal Science, 2015, 19(3), 977-988.

33.  Jiang LEI, Xian WANG*, Gongnan XIE. Turbulent Flow Field Analysis of a Jet in Cross Flow by DNS. Journal of Engineering Thermophysics, 2015, 24(3): 259-269. DOI: 10.1134/S1810232815030078.

32.   Jiang LEI, Xian WANG*, Gongnan XIE. High Performance Computation of a Jet in Crossflow by Lattice Boltzmann Based Parallel Direct Numerical Simulation. Mathematical Problems in Engineering, 2015, 956827, 1-11.

31.   上官燕琴, 王娴*, 李跃明. 基于格子Boltzmann方法的平板射流大涡模拟. 计算物理, 2015, 32(6): 669-676.

30.   上官燕琴, 王娴*, 李跃明. 气膜冷却掺混机理的高性能数值研究. 气体物理, 2015, 10(3): 76-83.

2014年

29.   Xian WANG*, Yanqin SHANGGUAN, Naoyuki ONODERA, Hiromichi KOBAYASHI, Takayuki AOKI. Direct Numerical Simulation and Large Eddy Simulation on a Turbulent Wall-Bounded Flow Using Lattice Boltzmann Method and Multiple GPUs. Mathematical Problems in Engineering, 2014, 742432, 1-10.

28.  Gang CHEN, Xian WANG*, Yueming LI. Reduced-Order-Model-Based Placement Optimization of Multiple Control Surfaces for Active Aeroelastic Control. International Journal of Computational Methods. 2014, 11(6), 1350081, 1-19. ( DOI: 10.1142/S0219876213500813)

27.  Gang CHEN, Xian WANG, Yueming LI. A reduced-order-model-based multiple-in multiple-out gust alleviation control law design method in transonic flow.Science China Technological Sciences, 2014, 57(2): 368-378. (DOI: 10.1007/s11431-013-5416-x)

2013年

26.  Xian WANG*, Hiroyuki Hirano, Gongnan Xie, Ding Xu. VOF Modeling and Analysis of the Segmented Flow in Y-Shaped Microchannels for Microreactor Systems. Advances in High Energy Physics, 2013, 732682, 1-6. (http://dx.doi.org/10.1155/2013/732682)

25. Xian WANG*, Hiroyuki Hirano, Gongnan Xie. A PLIC-VOF-Based Simulation of Water-Organic Slug Flow Characteristics in a T-Shaped Microchannel. Advances in Mechanical Engineering, 2013, 987428, 1-8. (http://dx.doi.org/10.1155/2013/987428)

24. Ding XU, Xian WANG* and Gonang XIE. Spectral Fixed Point Method for Nonlinear Oscillation Equation with Periodic Solution. Mathematical Problems in Engineering, 2013, 538716, 1-9.

23.  Gang CHEN, Xian WANG and Yueming LI. Active Aeroelastic Control Using Multiple Control Surfaces Based on High-fidelity Reduced Order Model. Transactions of the Japan Society for Aeronautical and Space Sciences, 2013, 56(5): 261-268.

22.    许丁, 陈刚, 王娴*, 李跃明. 基于多GPU 的格子Boltzmann 法对槽道湍流的直接数值模拟. 应用数学和力学, 2013, 34(9): 956-964.

21.    郭欣, 王娴, 许丁, 谢公南. 混合层无粘稳定性分析的Legendre 级数解. 应用数学和力学, 2013, 34(8): 782-794.

2012年

20.  Xian WANG*, Takayuki AOKI. High performance computation by multi-node GPUcluster-TSUBAME2.0 on the air flow in an urban city using lattice Boltzmann method. International Journal of Aerospace and Lightweight Structures, 2012, 2 (1): 77-86.

19. Takahito MIKI, Xian WANG, Takayuki AOKI. Patient-specific modeling of pulmonary air flow using GPU cluster for the application in medical practice. Computer Methods in Biomechanics and Biomedical Engineering, 2012, 15 (7): 771-778.

18. Hiroki Matsuno, Hiroyuki Hirano, Tomohiro Nakagawa, Xian WANG and Naotaka Okamoto, Alternating Flow of Immiscible Liquids in Microchannel, Asia-Pacific Journal of Chemical Engineering, 2012, 7: S48–S53.

2011年及以前

17.  Xian WANG*, Takayuki AOKI. Multi-GPU performance of incompressible flow computation by lattice Boltzmann method on GPU cluster. Parallel Computing, 2011, 37: 521-535.

16. Xian WANG*, Hiroyuki HIRANO, Naotaka OKAMOTO. Numerical investigation on the liquid-liquid two phase flow in a Y-shaped microchannel, ANZIAM J. (The Australian and New Zealand Industrial and Applied Mathematics Journal), 2008, 48 (C): C963--C976, MR2399323.

15.  Xian WANG, Hiroyuki HIRANO, Toshio TAGAWA, and Hiroyuki OZOE. Water mist flow in a super-conducting magnet inclined at various angles. Chemical engineering communications, 2007, 194: 835-848.

14.  Xian WANG, Hiroyuki HIRANO, Toshio TAGAWA, Hiroyuki OZOE, and Qiuwang WANG. The behavior of micro-scaled Brownian particles in a cylinder under natural and magnetic convection flow field of air. Numerical Heat Transfer, Part A: applications,2005, 47(4): 353-373. 

13.   Xian WANG, Hiroyuki HIRANO, Toshio TAGAWA, Hiroyuki OZOE, and Qiuwang WANG. Numerical computation for clustering of carbon particles with various sizes under both natural and magnetizing convections. Chemical Engineering Science, 2005, 60: 5105-5117.

12.    Xian WANG, Toshio TAGAWA, Hiroyuki OZOE, Hiroyuki HIRANO, and Qiuwang WANG. The behavior of a water droplet in a flow field of natural convection in a cubic enclosure with magnetic field. Progress in Computational Fluid Dynamics, 2005, 5(3/4/5): 271-280.

11.    Xian WANG, Shushen LU, Hiroyuki HIRANO, Toshio TAGAWA, and Hiroyuki OZOE. Experimental and computational studies on the water mist flow in a horizontal bore of a super-conducting magnet: example of magnetic force application on micron-sized objects. Japanese Journal of Applied Physics, 2005, 44(11): 8189-8195.

10.   Xian WANG, Hiroyuki HIRANO, Toshio TAGAWA, Hiroyuki OZOE, and Qiuwang WANG. The behavior of diamagnetic Brownian particles in the presence of a gradient magnetic field.  Journal of Chemical Engineering of Japan, 2005, 38(1): 24-33. 

9.   Shushen LU, Xian WANG, Hiroyuki HIRANO, Toshio TAGAWA, and Hiroyuki OZOE. Water mist flow in a vertical bore of a super-conducting magnet. Journal of Applied Physics, 2005, 98, 114906: 1-9.

8.   Qunwu HE, Qiuwang WANG, Xian WANG, and Laiqin LUO. DSMC simulation of low-speed gas flow and heat transfer in 2D rectangular micro-channel. Progress in Computational Fluid Dynamics, 2005, 5(3/4/5): 230-235. 

7.     王娴, 王秋旺, 陶文铨, 傅游, 康继昌. 直接模拟蒙特卡罗方法的并行方案设计. 西安交通大学学报, 2003, 37(1): 105-107.

6.     王秋旺, 王娴, 陶文铨, 郑平. 稀薄气体二维外部柱体绕流特性研究. 工程热物理学报, 2003, 24(2): 298-300.

5.     柏巍, 王秋旺, 王娴, 陶文铨. 矩形微通道内滑移区气体流动换热的数值模拟. 上海理工大学学报, 2003, 25(1): 1-4.  

4.     Xian WANG, Qiuwang WANG, Wenquan TAO and Ping Chueng. Simulation of rarefied gas flow and heat transfer in microchannels. Science in China, Series E- Technological Sciences, 2002, 45 (3): 321-327.

3.     王娴, 王秋旺, 陶文铨, 郑平. 直接模拟蒙特卡罗方法在微通道流动模拟中的应用. 工程热物理学报, 2002, 3S: 125-128.

2.   王娴，宋富强，屈治国，李明秀，王秋旺，陶文铨．场协同理论在椭圆型流动中的数值验证．工程热物理学报，2002，23(1)：59-62.

 1．王娴，王秋旺，陶文铨．三维方腔内层流自然对流特性的数值研究. 东北大学学报（自然科学版），2001，22 (S2)：61-63．

 

Conferences & Symposius：

 

2023年

1. XiangCheng Sun，Xian Wang*，Implementation of a three-dimensional rotor motion approach in fluids using LBM and level-set method on multiple GPUs. The 2nd International Symposium on Advances in Aerodynamics (SAIA 2023), 2023/12/8-2023/12/11, GuangZhou, China.
2. 许鹏飞, 王娴* . 螺旋蒸发管内二次流对其流动换热特性影响研究。工程热物理学会传热传质学术会议,2023/11/17-2023/11/20，中国 成都。
3. 张智慧, 王娴* . 基于微缝注入的平板发汗冷却近壁流动及传热机理研究。第十九届全国分离流、旋涡和流动控制会议，2023/7/21-2023/7/23，中国 西安。
4. 张智慧, 王娴*．多区耦合发汗冷却近壁流动传热机理研究。第二届中国空气动力学大会，2023/3/30-2023/4/3，中国 天津。
5. 吴小雨, 王娴*．基于相场理论的两相流格子玻尔兹曼模型GPU并行优化策略。第二十届全国计算流体力学会议，2023/6/24-2023/6/27，中国 哈尔滨。
6. 张宏明，肖光明，王娴*。含点阵单元的轻质防隔热结构传热性能研究。第十三届全国实验流体力学学术会议，2023/4/21-2023/4/24，中国 合肥。

2022年 

1. 张智慧, 王娴* . 多区耦合发汗冷却近壁涡系结构的演化. 第十二届全国流体力学学术会议, 2022/11/18-2022/11/21, 中国西安.
2. 吴小雨, 王娴* . 液滴撞壁空气夹带形成及其对换热的影响. 第十二届全国流体力学学术会议, 2022/11/18~2022/11/21, 中国西安.
3. 孔祥程, 王娴* . 基于LBM-GPU直接模拟方法的圆柱-翼型噪声特性研究. 第二届全国计算声学会议, 2022/8/12-2022/8/14, 中国胶州.
4. 孔祥壮, 张超, 肖光明, 杜雁霞, 王娴* . 各向异性多孔材料渗透率及换热特性数值研究. 2022中国工程热物理传热传质学术会议, 2022/12/16-2022/12/18, 武汉.
5. Xiaoyu Wu, Zhihui Zhang, Xian Wang* . Numerical Study on Air Entrapment of Three-dimensional Droplet Impingement. 31st DSFD Conference in conjunction with 10th Conference of LBM and its Applications, August 22~26, 2022, SuZhou, China.

2021年

53.祝衔琦, 孙祥程, 王娴* . 基于LBM-GPU与Level-Set的扑翼运动气动性能机理研究. 第十九届全国计算流体力学会议，2021/6/27-2021/6/30, 中国南京.

52.张超，肖光明，王娴*，杜雁霞*. 孔隙尺度下自然对流对泡沫铜等效导热系数影响的数值研究[C]. 第二届华人能源与人工环境国际学术会议，2021/7/16-2021/7/19, 中国成都.

2020年

51．李济源, 谢晓乐, 鲁海峰, 赵杨,张元哲,王娴^*,韩先伟 . 轨道高度对吸气式电推进气体捕集的影响研究[C]. 第十六届中国电推进学术研讨会，2020/12/25-2020/12/27, 中国北京.（获研讨会优秀论文奖）

50．王小伟,张智慧,王娴^*,结冰气象条件下压电式热合成双射流激励器性能数值模拟研究[C],第四届全国结冰与防除冰学术会议,2020/11/12-2020/11/14，中国重庆.

49．张超，肖光明，杜雁霞，王娴^*,A320座舱内流动传热特性的数值研究[C],全国环境风工程学术会议,2020/10/15-2020/10/16，中国北海.

2019年

48．张智慧，夏京京，邓雄，王娴*，罗振兵．合成双射流雾化冷却机理数值研究[C]．中国力学大会-2019，2019/8/25-2019/8/28，中国杭州．（获研讨会优秀论文奖）

47．Shao-zhen Guo, Guang-ming Xiao, Yan-xia Du, Xian Wang*, A study on thermal characterization of a square LHTS module with    both copper foam and multiple PCMs [C]. 5th International Workshop on Heat/Mass Transfer Advances for Energy Conservation and  Pollution Control, August 13-16, 2019, Novosibirsk, Russia.

46．Chao Zhang, Xian Wang*, Hu Zhang, Simulation of natural convection coupling with radiation in a square cavity by lattice Boltzman  method [C]. The 7th Asian Symposium on Computational Heat Transfer and Fluid Flow- 2019, September 3-7, 2019, Tokyo, Japan.

45．Chen-Yang Shang, Zhuo-Ran Liu, Hu Zhang*, Xian Wang , Yue-Ming Li, Thermal insulation performance characterization of thermal protection material under large temperature difference and its thermal conductivity identification [C]. 5th International Workshop on Heat/Mass Transfer Advances for Energy Conservation and Pollution Control, August 13-16, 2019, Novosibirsk, Russia.

44．Hu Zhang*, Xian Wang, Yue-Ming Li, Gui-Hua Tang, Influence of participating Thermal radiation within translucent insulation materials on the thermal conductivity measured by hot strip method [C]. The 7th Asian Symposium on Computational Heat Transfer and Fluid Flow- 2019, September 3-7, 2019, Tokyo, Japan.

43．Yi-Xin Ma, Hu Zhang*, Xian Wang, Yue-Ming Li, Gui-Hua Tang, A numerical study of the uncertainty analysis of TCi method [C].  The 7th Asian Symposium on Computational Heat Transfer and Fluid Flow- 2019, September 3-7, 2019, Tokyo, Japan.

2018年

42．Jingjing XIA, Chao ZhANG, Xian WANG*, Hu. ZHANG, High Performance Numerical Study of Flow and Heat Transfer in Simplified Models  of Spacecraft Cabin under Various Ventilation Angles. XI-th International Conference on Computational Heat, Mass and Momentum Transfer(ICCHMT 2018), May 20-24, 2018, Cracow, Poland.

41．Hu ZHANG, Yixin MA, Xian WANG, Yueming LI, Wenquan TAO, Influence of radiative heat transfer on measuring thermal conductivity of  semi-transparent materials with hot wire method. XI-th International Conference on Computational Heat, Mass and Momentum Transfer(ICCHMT 2018), May 20-24, 2018, Cracow, Poland.

2017年

40．Yanqin SHANGGUAN, Xian WANG*, Yueming LI. Large-scaled numerical investigation on film cooling with cascaded double  jets. 4th International Workshop on Heat Transfer, IWHT2017, April 2-5, 2017, Las Vegas, NV, USA (paper no. TFEC-IWHT2017-17494)

2016年

39．上官燕琴, 王娴*, 李跃明. 气膜冷却中反对称涡生成机制的大规模高性能数值研究. 第九届全国流体力学学术会议, 2016/10/20-  2016/10/23, 中国南京, 文章编号: CSTAM 2016-P56-B9068.

38．张保雷, 王娴*, 陈刚，李跃明. 不同吹风比下横向流中平板单孔射流涡结构的实验研究. 第九届全国流体力学学术会议, 2016/10/20-  2016/10/23, 中国南京, 文章编号: CSTAM 2016-P56-B0823.

37．王娴*. GPU高性能计算及其在计算流体力学中的应用。中核核反应堆热工水力技术重点实验室学术交流会，2016/11/16-2016/11/18，中国 成都。（特邀报告）

36．Zhen LI, Xian WANG, Yueming LI. The study of periodic of beam band gap charateristics when considering thermal effect, 035-01, The Chinese  Conference on Computational Mechnaicw'2016 in conjunction with the 4th Qian Ling-Xi Computational Mechanics Awarding Ceremony, The    International Symposium on Computaional Mechanics'2016. (CCCM-ISCM 2016), 中国计算力学大会2016暨第四届钱令希计算力学奖颁奖大 会，国际华人计算力学大会2016，2016/10/16-2016/10/20，中国杭州。

35．Yanqin SHANGGUAN, Xian WANG*, Yueming LI. Further investigation on the mixing mechanism of single-jet film cooling based on hybrid      thermal lattice Boltzmann method. The 25th International Conference on Discrete Simulation of Fluid Dynamics (DSFD 2016). 2016/07/03-07/08,  ShenZhen, China.

34. Yanqin SHANGGUAN, Xian WANG*, Yueming LI. GPU-based parallel simulation of film cooling by hybrid thermal lattice Boltzmann method. European Congress on Computational Methods in Applied Sciences and Engineering (ECCOMAS 2016). 2016/06/05-06/10, Crete, Greece.

33．王娴*．气膜冷却掺混机理的大规模数值研究。四校航空航天及力学学术论坛 2016，2016/05/13-2016/05/15, 浙江，舟山。

32．王娴*. GPU高性能计算在计算流体力学中的应用。Tesla GPU如虎添翼神州巡展2016-GPU技术与科学计算应用研讨会,2016/06/24，中国 西安。（特邀报告）

2015年

31.   赵鑫, 王娴, 李跃明. 潮湿环境下正交各向异性圆柱壳的声振响应研究. 第十二届军事海洋战略与发展论坛, 2015/11/04-   2015/11/06, 中国长沙, 论文集 pp 949-956.

30.   上官燕琴, 王娴*, 李跃明. 气膜冷却掺混机理的大规模数值研究.中国力学大会-2015, 2015/8/15-2015/8/18, 中国上海, 文章编号: CSTAM2015-A34-8821.

29.   王娴*, 上官燕琴, 李跃明. 基于格子Boltzmann方法的气膜冷却掺混机理大规模高性能数值研究, 第九届全国流体力学青年研讨会, 2015/5/9-2015/5/10, 中国长沙, 论文集 pp 152-159.

28.  Yanqin SHANGGUAN, Xian WANG*, Yueming LI. Large-scale numerical study on the mixing mechanism of film cooling based on LBM-LES with GPU acceleration. The 2nd Mechanical Engineering Seminar, 2015/03/25-27, Suwa, Japan.

27.  Xian WANG*. Numerical investigation on the mixing mechanism of double-jet film cooling. The 2nd KAIST-XJTU Joint Workshop on Mechanical and Aerospace Engineering. 2015/10/09-10, Xi’an, China.

2014年

26.  上官燕琴, 王娴^*, 陈刚, 李跃明. 基于格子Boltzmann方法的平板射流高性能数值模拟. 第八届全国流体力学学术会议, 2014/9/18-2014/9/21, 中国兰州,文章编号: CSTAM 2014-A26-S09063.

25.   雷蒋, 上官燕琴, 王娴^*, 陈刚, 李跃明. 平板射流格子Boltzmann方法数值模拟. 第八届全国流体力学学术会议, 2014/9/18-2014/9/21, 中国兰州, 文章编号: CSTAM 2014-B01-0255.

24.   Xian WANG*. High performance computation of incompressible flow by lattice Boltzmann method on GPU cluster. The 1st KAIST-XJTU Joint Workshop on Mechanical and Aerospace Engineering. 2014/08/18-19, Daejeon, Korea.

2013年

23.  Yanqin SHANGGUAN, Gang CHEN,Xian WANG*,Yeming LI. Large eddy simulation of high Reynolds number turbulent flowsusing lattice Boltzmann method and CUDA-GPU, 24th International Symposium on Transport Phenomena (ISTP24), 2013/11/1-2013/11/5, Yamaguchi, Japan.

22.  Gang CHEN,Xian WANG,Yueming Li. A Reduced-Order-Model-Based Multiple-in Multiple-out Gust Alleviation ControlLaw Design for Transonic Aeroelastic wings, Asia-Pacific Congress for Computational Mechanics(APCOM2013),2013/12/11-2013/12/14, Singapore.

21.   上官燕琴, 陈刚, 王娴*,李跃明. 基于GPU格子-Boltzmann法的湍流大涡模拟,中国力学大会-2013, 2013/8/18-2013/8/19, 中国西安, 文章编号: CSTAM2013-A31-1095.

20.   王娴*, 陈刚, 李跃明. 基于多GPU并行的湍流数值模拟, 第八届全国流体力学青年研讨会,2013/5/18-2013/5/19,中国上海, 论文集pp 145-151.

2012年

19.   Hiroyuki HIRANO，Xian WANG. Dimensionless Correlation in Alternating Flow of Immiscible Liquids in Microchannel, the 14th Asia Pacific Confederation of Chemical Engineering Congress (APCChE 2012), 2012/02/21-2012/02/24, Singapore , pp 429-430.

2011年及以前

18.  Xian WANG*and Takayuki AOKI. Simulation of air flow in an urban city by lattice Boltzmann method on multi-node GPU cluster. Second International Conference on Computational Methods for Thermal Problems, 2011/9/5-2011/9/7, Dalian, China.

17.  Xian WANG and Takayuki AOKI. Application of Multi-GPU on the Simulation of Air Flow in an Urban City by Lattice Boltzmann Method. International Workshop of GPU Solutions to Multiscale Problems in Science and Engineering, 2011/7/18-2011/7/21, Lanzhou, China.

16.  Takahito MIKI, Xian WANG, Takayuki AOKI, Yohsuke IMAI, Takuji ISHIKAWA, Kei TAKASE, and Takami Yamaguchi. Subject-specific pulmonary airflow simulation by lattice Boltzmann method on GPU cluster. SIAM Conference on Computational Science and Engineering (SIAM CSE11), 2011/3/3, Reno, Nevada, America.

15. Xian WANG and Takayuki AOKI. High performance of lattice Boltzmann method on multi-node GPU cluster and its application on incompressible flow computation. Joint International Conference on Supercomputing in Nuclear Applications and Monte Carlo 2010 (SNA + MC2010), 2010/10/21, Tokyo, Japan.

14.  Takayuki AOKI, Marlon Arce ACUNA, Xian WANG, Satoi OGAWA. Large-scale CFD applications on multi-node GPU cluster. Fifth European Conference on Computational Fluid Dynamics (ECCOMAS CFD 2010), Proceedings, 2010/6/17, Lisbon, Portugal, P.697.

13.  王嫻, 青木尊之, GPGPU を用いた格子ボルツマン法による非圧圧性流体計算, 計算工学講演会, 2010/05/14-2010/05/14, 福岡, 日本, pp 311-314.

12.  Xian WANG,Takayuki AOKI. Comparison on the performance of Lattice Boltzmann method solver executed onmulti-node GPU cluster by multi-dimensional domaindecompositions, 第15回計算工学講演会, 2010/05/26-2010/05/28, Fukuoka, Japan, pp 141-144.

11. Hiroyuki HIRANO,Xian WANG. Alternating Flow of Immiscible Liquids inMicrochannel, the 13th Asia Pacific Confederation of Chemical Engineering Congress (APCChE 2010), 2010/10/05-2010/10/08, Taipei, Taiwan.

10. Xian WANG, Hiroyuki HIRANO, Qiuwang WANG, Shushen LU, Toshio TAGAWA,and Hiroyuki OZOE. Numerical computation on the combined effect of magnetic force and natural convection for clustering and levitating of Brownian particles. 13th International Heat Transfer Conference, 2006/8/13-2006/8/18, Sydney, Australia, NCV-18.

9.   Xian WANG, Hiroyuki HIRANO, Toshio TAGAWA, and Hiroyuki OZOE. Magnetic effect on the water mist flow and numerical simulation on the Brownian motion. The 16th International Symposium on Transport phenomena, 2005/8/29-2005/9/1, Prague, Czech Republic.

8.  Xian WANG, Hiroyuki HIRANO, Toshio TAGAWA, and Hiroyuki OZOE. The effect of natural and magnetic convection on the behavior of Brownian particles. The 10th Asian Pacific Confederation of Chemical Engineering (APCCHE) Congress, 2004/10/17-2004/10/21, Kitakyushu, Japan.

7.  Qiuwang WANG, Xian WANG, Toshio TAGAWA, and Hiroyuki OZOE. Numerical investigation on natural convection of water in porous layer under magnetic field. The 6th International Symposium on Heat Transfer, 2004/6/15-2004/6/19, Beijing, China, pp 281-285.

6.  Xian WANG, Toshio TAGAWA, Hiroyuki HIRANO, Hiroyuki OZOE, and Qiuwang WANG. Numerical study for the behavior of particles with 5µm diameters in natural and magnetic convection fields. The 15th International Symposium on Transport phenomena, 2004/5/9-2004/5/13, Bangkok, Thailand, pp 309-313. 

5.  Qunwu HE, Qiuwang WANG, Xian WANG and Hiroyuki OZOE. Computational investigation of low-speed gas flow and heat transfer in micro-channel using DSMC with pressure boundary condition. Heat Transfer 2004 – Eighth International Conference on Advanced Computational Methods in Heat Transfer, 2004/3/24-2004/3/26, Lisbon, Portugal, pp 463-469.

4.  Xian WANG, Toshio TAGAWA, and Hiroyuki OZOE. Numerical computation of the levitation of a water droplet in a strong magnetic field. Proceedings of the International Conference on Fluid and Thermal Energy Conversion, 2003/12/7-2003/12/11, Bali, Indonesia, no.19, 1-7.

3.  Xian WANG, Toshio TAGAWA and Hiroyuki OZOE. Numerical simulation of the movement of Brownian water droplets in both the natural convection flow field and magnetic field. The 16th Symposium on Chemical Engineering, 2003/12/5-2003/12/6, Daejeon, Korea, pp 188-189.

2.  Xian WANG, Toshio TAGAWA, Hiroyuki OZOE and Qiuwang WANG. Numerical computation for particles separation with a magnetic field. Symposium on New Magneto-Science, Proceedings of the 7th Meeting, 2003/11/5-2003/11/7, Tsukuba, Japan, pp 253-257.

1.   Xian WANG, Qiuwang WANG and Wenquan TAO. Parallel implementation of microchannel gas flow by direct simulation of Monte Carlo. International Symposium on “Micro/Nanoscale Energy Conversion and Transport”, 2002/4/14-2002/4/19, Antalya, Turkey.