菅永军

学习经历	起止年月	学校	专业	学位/学历
基本信息	姓名	菅永军
	系室	数学系
	职称	教授
	联系方式	见学院黄页
	电子邮件	jianyj@dhu.edu.cn
	研究方向	应用数学、流体力学，包括微纳尺度流体力学、非牛顿流体力学、水动力学和流动的稳定性、热质传输等。
	个人简介	菅永军，男，汉族，1974年生，民盟盟员，内蒙古大学数学科学学院教授，博士生导师。2003年获中国科学院力学研究所流体力学专业博士学位。 2020年当选第十一届流体力学专业委员会微纳尺度流动专业组组员，第十一届流体力学专业委员会非牛顿流体力学专业组组员。现任内蒙古数学学会理事，曾任山东省声学学会副理事长，中山大学第三层次百人计划入选者。国家自然基金通讯评审专家，2014年和2021年受聘内蒙古大学学校、学部和教授三级委员会委员。担任多个国内外著名杂志，如 Journal of Fluid Mechanics, Physics of fluids, International Journal of Heat and Mass Transfer，《物理学报》等的审稿人。主持包括国家自然基金面上项目等科研项目10余项，已发表包括流体力学学科方面的顶级SCI期刊Journal of Fluid Mechanics, Physics of fluids以及Journal of Non-Newtonian Fluid Mechanics等收录论文120余篇。指导国家级大学生创新项目4项，自治区研究生创新项目7项。指导的研究生中14人获国家奖学金，1人获第九届中国青少年科技创新奖，1人获自治区奖学金，1人获乌可力奖学金，2人获内蒙古大学校长励学奖优秀硕士和优秀博士学生奖，3位博士生获内蒙古自治区优秀博士学位论文。
	1998/09-2003/01	中国科学院力学研究所	流体力学	博士学位
	1995/09-1998/07	内蒙古大学数学系	应用数学	硕士学位
	1991/09-1995/07	内蒙古师范大学数学系	数学	学士学位
工作经历	起止年月	单位	职称/职务
	2003/03-2005/12	国家海洋局第一海洋研究所	博士后
	2006/06-2009/04	中山大学工学院	副教授、硕士生导师
	2009/06-2024/01	内蒙古大学数学科学学院	教授、博士生导师
	2012/09-2013/09	美国Cornell大学化学与生物分子工程学院	访问学者
	2017/09-2018/07	北京大学工学院	访问学者
	2018/02-2018/05	美国Texas大学Rio Grande Valley分校	访问学者
	2024/02-至今	东华大学理学院	教授、硕士生导师、博士生导师
教学成果	课程名称
教学成果	近年来主讲了本科生的基础专业课《数学物理方程》、《常微分方程》以及硕士研究生的基础专业课《偏微分方程》、《流体力学》、《微尺度流体力学》等。在教学工作中，始终坚持为人师表，尊重学生，确立以学生为主体，以培养学生主动发展为中心的教学思想，重视学生的个性发展，重视激发学生的创造能力。
科研成果	研究名称
科研成果	主持的项目： 1. 主持国家自然科学基金地区项目: 电磁场作用下奇粘性对微尺度薄液膜不稳定性的影响(项目编号：12262026)，时间：2023.01–2026.12； 2. 主持内蒙古自治区高等学校创新团队发展计划项目：应用数学、流体力学 (项目编号：NMGIRT2323)，时间：2023.01–2025.12； 3. 主持内蒙古自然基金面上项目: 碳纳米管内包含非牛顿流体的不稳定性研究(项目编号：2021MS01007)，时间：2021.01–2023.12； 4. 主持内蒙古自治区党委组织部: 2019年“草原英才”滚动支持项目(项目编号：12000-12102408)，时间：2019.11–2021.11； 5. 主持国家自然科学基金面上项目: 微纳通道中物理特性随压力变化的流体的电动能量转化 (项目编号：11772162)，时间：2018.01–2021.12； 6. 主持国家自然科学基金面上项目: 垂向磁场作用下微通道内的电渗流动与传热研究(项目编号：11472140)，时间：2015.01–2018.12； 7. 主持国家自然科学基金地区项目: 两层流体Faraday 界面波动力学研究(项目编号：11062005)，时间：2011.01–2013.12； 8. 主持内蒙古自然基金面上项目: 柔性纳米管道中电渗流动(项目编号：2016MS0106)，时间：2016.01–2018.12； 9. 主持内蒙古自治区党委组织部: 2015年入选内蒙古自治区第五批“草原英才”(项目编号：12000-12102013)，时间：2015.11–2018.11； 10. 主持内蒙古自治区高等学校“青年科技领军人才”项目: 微流体管道中非牛顿流体的非定常电渗流动(项目编号：NJYT-13-A02)，时间：2013.01–2014.12； 11. 主持内蒙古自然科学基金项目: 双频垂直激励两层流体的 Faraday 界面波(项目编号：2010BS0107)，时间：2010.01–2012.12； 12. 主持中科院力学所LNM国家重点实验室开放基金项目:微管道中具有自由面的非牛顿流体的电渗流动，时间：2012.01–2013.12；

代表性论文&科研
2024年
1. Beinan Jia, Yongjun Jian*, The effect of Oldroyd-B fluid on thermal convection stability in a bidispersive porous media with relatively large macropores, Physics of Fluids, 2024, 36, 014105.
2. Xingyu Chen, Zhiyong Xie, Yongjun Jian*, Streaming potential of viscoelastic fluids with the pressure-dependent viscosity in nanochannel. Physics of Fluids, 2024, 36, 032025.
3. Long Chang, Guangpu Zhao, Mandula Buren, Yanjun Sun, and Yongjun Jian*, Alternating Current Electroosmotic Flow of Maxwell Fluid in a Parallel Plate Microchannel with Sinusoidal Roughness, Micromachines, 2024, 15(1), 4.
4. 孙艳军，王嘉璐，贾北楠，菅永军*，非傅里叶效应对Maxwell流体在垂直槽道中热对流不稳定性的影响，力学学报，2024，待发表.
5. 长龙，布仁满都拉，孙艳军，菅永军*，具有正弦波纹的平行板微通道中Jeffrey流体周期电渗流动，应用数学和力学，2024，待发表.
2023年
6. Zhiyong Xie, Yongjun Jian*, Xingyu Chen, Electrokinetic energy conversion of high pressure-driven flow with pressure-viscosity effect at high zeta potential, International Journal of Engineering Science, 2023, 184,103819.
7. Beinan Jia, Yongjun Jian*,Stability of a liquid film on inclined flexible substrates: Effect of the spontaneous odd viscosity, Physical Review E, 2023, 108, 045104.
8. Xin Chu, Yongjun Jian*, Electrostatically induced Faraday instability of thin film with spontaneous odd viscosity, Journal of Non-Newtonian Fluid Mechanics, 2023, 314, 105013.
9. Jialu Wang, Yanjun Sun, Yongjun Jian*, Rayleigh-Taylor instability of viscous liquid film under an inclined substrate with time modulated temperature, International Communications in Heat and Mass Transfer, 2023, 142, 106677.
10. Siyi An, Yongjun Jian*,Rayleigh–Taylor instability of viscoelastic self-rewetting film flowing down a temperature-controlled inclined substrate, Chinese Physics B, 2023, 32, 064701.
11. Nailin Ma, Yanjun Sun, Yongjun Jian*, Electromagnetohydrodynamic (EMHD) Flow in a Microchannel with Random Surface Roughness, Micromachines, 2023, 14, 1617.
12. Zhili Wang, Yanjun Sun, Yongjun Jian*,The Effect of Random Roughness on the Electromagnetic Flow in a Micropipe, Micromachines, 2023, 14, 2054.
13. Jiaxuan Zheng, Jialu Wang, Yongjun Jian*, Micro Electro-Osmotic Thrusters of Power-Law Fluids for Space Propulsion, Micromachines, 2023, 14, 949.
14. 郑佳璇，梁韵笛，菅永军*，高Zeta势下Phan-Thien-Tanner(PTT)流体的电渗微推进器，应用数学和力学，2023，44(10), 1213–1225.
15. Xue Gao, Guangpu Zhao, Na Li, Ying Zhang, Yongjun Jian*, The electrokinetic energy conversion analysis of Newtonian fluids with pressure-dependent viscosity in rectangular nanotube, Journal of Molecular Liquids, 2023, 371, 121022.
2022年
16. Yongjun Jian*, Electrokinetic energy conversion of fluids with pressure-dependent viscosity in nanofluidic channels, International Journal of Engineering Science, 2022, 170,103590.
17. Beinan Jia, Yongjun Jian*, The effect of odd-viscosity on Rayleigh–Taylor instability of a liquid film under a heated inclined substrate, Physics of Fluids, 2022, 34, 044101.
18. Xin Chu, Long Chang, Beinan Jia, Yongjun Jian*, Effect of the odd viscosity on Faraday wave instability, Physics of Fluids, 2022, 34, 114123.
19. Zhiyong Xie, Yongjun Jian*, Electrokinetic energy conversion of power-law fluids in a slit nanochannel beyond Debye-Hückel linearization, Energy, 2022, 252, 124029.
20. Yongbo Liu, Jingnan Xing, Yongjun Jian*, Heat transfer and entropy generation analysis of electroosmotic flows in curved rectangular nanochannels considering the influence of steric effects, International Communications in Heat and Mass Transfer, 2022, 139, 106501.
21. Shujuan An, Kai Tian, Zhaodong Ding, Yongjun Jian*, Electroosmotic and pressure-driven slip flow of fractional viscoelastic fluids in microchannels, Applied Mathematics and Computation, 2022, 425, 127073.
22. Zhaodong Ding, Kai Mu, Ting Si, Yongjun Jian*, Linear instability analysis of a viscoelastic jet in a co-flowing gas stream, Journal of Fluid Mechanics, 2022, 936, A6.
23. Xin Chu, Yongjun Jian*, Electrokinetic energy conversion through cylindrical microannulus with periodic heterogeneous wall potentials, Journal of Physics D: Applied Physics, 2022, 55, 145501.
24. Xingyu Chen, Yongjun Jian*, Entropy generation minimization analysis of two immiscible fluids, International Journal of Thermal Sciences, 2022, 171,107210.
25. Xingyu Chen, Yongjun Jian*, Zhiyong Xie, Slippery electrokinetic flow of viscoelastic fluids with pressure-dependent viscosity and relaxation time. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2022, 639, 128354.
26. Zhaodong Ding, Long Chang, Kai Tian, Yongjun Jian*, On the energy conversion in electrokinetic transports, Applied Mathematics and Mechanics (English Edition), 2022, 43(2), 263–274.
27. Shujuan An, Kai Tian, Zhaodong Ding, Yongjun Jian*, Electromagnetohydrodynamic (EMHD) flow of fractional viscoelastic fluids in a microchannel, Applied Mathematics and Mechanics (English Edition), 2022, 43(6), 917–930.
28. Xingyu Chen, Yongjun Jian*, Heat transfer of nanofluid with electroviscous effect in MHD-based microannulus, Journal of Thermal Analysis and Calorimetry, 2022, 147, 2715–2728.
29. Long Chang, Yanjun, Sun, Mandula Buren, Yongjun Jian*, Thermal and Flow Analysis of Fully Developed Electroosmotic Flow in Parallel-Plate Micro- and nanochannel with Surface Charge-Dependent Slip, Micromachines, 2022, 13, 2166.
30. Jiali Zhang, Guangpu Zhao, Xue Gao, Na Li, Yongjun Jian**, Streaming potential and electrokinetic energy conversion of nanofluids in a parallel plate microchannel under the time-periodic excitation, Chinese Journal of Physics, 2022, 75, 55–68.
31. Na Li, Guangpu Zhao, Xue Gao, Ying Zhang, Yongjun Jian*, The impacts of viscoelastic behavior on electrokinetic energy conversion for Jeffreys fluid in microtubes, nanomaterials, 2022, 12, 3355.
32. Xinyue Bian, Fengqin Li * and Yongjun Jian, The Streaming Potential of Fluid through a Microchannel with Modulated Charged Surfaces, Micromachines, 2022, 13, 66.
2021年
33. Zhaodong Ding, Yongjun Jian*, electrokinetic oscillatory flow and energy conversion of viscoelastic fluids in microchannels: a linear analysis, Journal of Fluid Mechanics, 2021, 919, A20.
34. Gaowa Bao, Yongjun Jian*, Odd-viscosity-induced instability of a falling thin film with an external electric field, Physical Review E, 2021, 103, 013104.
35. Xingyu Chen, Yongjun Jian*, Zhiyong Xie, Electrokinetic flow of fluids with pressure-dependent viscosity in a nanotube, Physics of Fluids, 2021, 33, 122002.
36. Zhaodong Ding, Yongjun Jian*, Resonance behaviors in periodic viscoelastic electrokinetic flows: a universal Deborah number, Physics of Fluids, 2021, 33, 032023.
37. Jiaxuan Zheng, Siyi An, Yongjun Jian*, Steric effects on electroosmotic nano-thrusters under high zeta potentials, Mathematics, 2021, 9, 3222.
38. Guangpu Zhao, Jiali Zhang, Zhiqiang Wang, Yongjun Jian*, Electrokinetic energy conversion of electromagnetohydrodynamic (EMHD) nanofluids through a microannulus under the time-periodic excitation, Applied Mathematics and Mechanics (English Edition), 2021, 42(7), 1029–1046.
39. Jiaxuan Zheng, Beinan Jia, Yongjun Jian*, Steric effects on space electroosmotic thrusters in soft nanochannels, Mathematics, 2021, 9, 1916.
40. Jiaxuan Zheng, Yongjun Jian*, Space electroosmotic thrusters in ion partitioning soft nanochannels, Micromachines, 2021, 12, 777.
41. Beinan Jia, Yongjun Jian*, Instability of single-walled carbon nanotubes conveying Jeffrey fluid, Chinese Physics B, 2021, 30(4), 044601.
42. Juanxia Zhao, Yongjun Jian*, Effect of odd viscosity on the stability of a falling thin film in presence of electromagnetic field, Fluid Dynamics Research, 2021, 53, 015510.
43. Juanxia Zhao, Yongjun Jian*, Effect of odd viscosity on the stability of thin viscoelastic liquid film flowing along an inclined plate, Physica Scripta, 2021, 96, 055241.
2020年
44. Jiaxuan Zheng, Yongjun Jian*, Electroosmotic thrusters in soft nanochannels for space propulsion, Physics of Fluids, 2020, 32,122005.
45. Meizhen Xu, Yongjun Jian*, Unsteady rotating electroosmotic flow with time-fractional Caputo-Fabrizio derivative, Applied Mathematics Letters, 2020, 100, 106015.
46. Yongbo Liu, Yongjun Jian*, Chunhong Yang, Electrochemomechanical energy conversion efficiency in curved rectangular nanochannels, Energy, 2020, 198, 117401.
47. Zhiyong Xie, Yongjun Jian*, Electrokinetic energy conversion of nanofluids in MHD-based microtube, Energy, 2020, 212, 118711.
48. Na Hao, Yongjun Jian*, Instability analysis of carbon nanotubes conveying viscoelastic fluid, Journal of Physics D: Applied Physic, 2020, 53, 11LT01.
49. Yongbo Liu, Yongjun Jian*, Chunhong Yang, Steric-effect-induced enhancement of electrokinetic energy conversion efficiency in curved nanochannels with rectangular sections at high zeta potentials, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2020, 591, 124558.
50. Yongbo Liu, Yongjun Jian*, Chunhong Yang, On electromagnetohydrodynamic flows and mass transport in curved rectangular microchannels, Applied Mathematics and Mechanics (English Edition), 2020, 41, 1431–1446.
51. Chunhong Yang, Yongjun Jian*, Effect of patterned hydrodynamic slip on electromagnetohydrodynamic flow in a parallel plate microchannel, Chinese Physics B, 2020, 29(11), 11410.
52. Chunhong Yang, Yongjun Jian*, Zhiyong Xie, Fengqin Li, Electromagnetohydrodynamic electroosmotic flow and entropy generation of third-grade fluids in a parallel microchannel, Micromachines, 2020, 11, 418.
53. 王爽，菅永军*，周期壁面电势调制下平行板微管道中的电磁电渗流动，应用数学和力学，2020, 41(4) , 396–405.
2019年
54. Zhaodong Ding, Yongjun Jian*, Wenchang Tan, Electrokinetic energy conversion of two-layer fluids through nanofluidic channels, Journal of Fluid Mechanics, 2019, 863, 1062–1090.
55. Xin Chu, Yongjun Jian*, Magnetohydrodynamic electroosmotic flow of Maxwell fluids with patterned charged surface in narrow confinements, Journal of Physics D: Applied Physic, 2019, 52, 405003.
56. Guangpu Zhao, Zhiqiang Wang, Yongjun Jian*, Heat transfer of the MHD nanofluid in porous microtubes under the electrokinetic effects, International Journal of Heat and Mass Transfer, 2019, 130, 821–830.
57. Yongbo Liu, Yongjun Jian*, The effects of finite ionic sizes and wall slip on entropy generation in electroosmotic flows in a soft nanochannel, Journal of Heat Transfer, 2019, 141, 102401.
58. Chunhong Yang, Yongjun Jian*, Zhiyong Xie, Fengqin Li, Heat transfer characteristics of Magnetohydrodynamic electroosmotic flow in a rectangular microchannel, European Journal of Mechanics / B Fluids, 2019, 74, 180–190.
59. Yongbo Liu, Yongjun Jian*, Rotating electroosmotic flows through soft parallel plate microchannels, Applied Mathematics and Mechanics (English Edition), 2019, 40(7), 1017–1028.
60. Yongbo Liu, Yongjun Jian*, Electroviscous effect on electromagnetohydrodynamic flows of Maxwell fluids in parallel plate microchannels, Applied Mathematics and Mechanics (English Edition), 2019, 40(10), 1457–1470.
61. Fengqin Li, Yongjun Jian*, Mandula Buren, Long Chang, Effects of three-dimensional surface corrugations on electromagnetohydrodynamic flow through microchannel, Chinese Journal of Physics, 2019, 60, 345–361.
62. Mandula Buren, Yongjun Jian*, Yingchun Zhao, Long Chang, Quansheng Liu, Effects of surface charge and boundary slip on time-periodic pressure-driven flow and electrokinetic energy conversion in a nanotube, Beilstein Journal of Nanotechnology, 2019, 10, 1628–1635.
63. Zehua Wang, Yongjun Jian*, Heat transport of electrokinetic flow in slit soft nanochannels, Micromachines, 2019, 10, 34.
64. Guangpu Zhao, Yongjun Jian*, Thermal transport of combined electroosmotically and pressure driven nanofluid flow in soft nanochannels, Journal of Thermal Analysis and Calorimetry, 2019, 135, 379–391.
65. Na Hao, Yongjun Jian*, Magnetohydrodynamic electroosmotic flow with patterned charged surface and modulated wettability in a parallel plate microchannel, Communications in Theoretical Physics, 2019, 71, 1163–1171.
66. 许丽娜，菅永军*，柔性圆柱形微管道内的电动流动及传热研究，应用数学和力学，2019, 40(4), 408–418
2018年
67. Zhiyong Xie, Yongjun Jian*, Wenchang Tan, Streaming potential analysis and electrokinetic energy conversion efficiency of two immiscible fluids in a nanochannel, Sensors & Actuators: B. Chemical, 2018, 273, 1257–1268.
68. Zhiyong Xie, Yongjun Jian*, Entropy generation of magnetohydrodynamic electroosmotic flow in two-layer systems with a layer of non-conducting viscoelastic fluid, International Journal of Heat and Mass Transfer, 2018, 127 Part B, 600–615.
69. Yongbo Liu, Yongjun Jian*, Wenchang Tan, Entropy generation of Electromagnetohydrodynamic (EMHD) flow in a curved rectangular microchannel, International Journal of Heat and Mass Transfer, 2018, 127 Part A, 901–913.
70. Zhiyong Xie, Yongjun Jian*, Fengqin Li, Thermal transport of magnetohydrodynamic electroosmotic flow in circular cylindrical microchannels, International Journal of Heat and Mass Transfer, 2018, 119, 355–364.
71. Jiaxuan Zheng, Yongjun Jian*, Rotating electroosmotic flow of two-layer fluids through a microparallel channel, International Journal of Mechanical Sciences, 2018, 136,. 293–302.
72. Mandula Buren, Yongjun Jian*, Yingchun Zhao, Long Chang, Electroviscous effect and electrokinetic energy conversion in time periodic pressure-driven flow through a parallel-plate nanochannel with surface charge-dependent slip, Journal of Physics D: Applied Physic, 2018, 51, 205601.
73. Xingyu Chen, Yongjun Jian*, Zhiyong Xie, Zhaodong Ding, Thermal transport of electromagneto- hydrodynamic in a microtube with electrokinetic effect and interfacial slip, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2018, 540, 194–206.
74. Jingnan Xing, Yongjun Jian*, Steric effects on electroosmotic flow in soft nanochannels, Meccanica, 2018, 53, 135–144.
75. Guangpu Zhao, Yongjun Jian*, Heat transfer of the nanofluid in soft nanochannels under the effects of the electric and magnetic field, Powder Technology, 2018, 338, 734–743.
76. Xingyu Chen, Yongjun Jian*, Streaming potential analysis on the hydrodynamic transport of pressure-driven flow through a rotational microchannel, Chinese Journal of Physics, 2018, 56, 1296–1307.
2017年
77. Zhiyong Xie, Yongjun Jian*, Entropy generation of two-layer magnetohydrodynamic electroosmotic flow through microparallel channels, Energy, 2017, 139, 1080–1093.
78. Zhaodong Ding, Yongjun Jian*, Liangui Yang, Analytical investigation of electrokinetic effects of micropolar fluids in nanofluidic channels, Physics of Fluids, 2017, 29, 082008.
79. Huicui Li, Yongjun Jian*, Dispersion for periodic electro-osmotic flow of Maxwell fluid through a microtube, International Journal of Heat and Mass Transfer, 2017, 115, 703–713.
80. Zhiyong Xie, Yongjun Jian*, Rotating electromagnetohydrodynamic flow of power-law fluids through a microparallel channel, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2017, 529, 334–345.
81. Yongjun Jian*, Fengqin Li, Yongbo Liu, Long Chang, Quansheng Liu, Liangui Yang, Electrokinetic energy conversion efficiency of viscoelastic fluids in a polyelectrolyte-grafted nanochannel, Colloids and Surfaces B: Biointerfaces, 2017, 156, 405–413.
82. Fengqin Li, Yongjun Jian*, Zhiyong Xie, Yongbo Liu, Quansheng, Liu, Transient alternating current electroosmotic flow of the Jeffrey fluid through a polyelectrolyte-grafted nanochannel. RSC Advances, 2017, 7, 782–790.
83. Guangpu Zhao, Yongjun Jian*, Fengqin Li, Electromagnetohydrodynamic flow and heat transfer of nanofluid in a parallel plate microchannel, Journal of Mechanics, 2017, 33, 115–124.
84. Fengqin Li, Yongjun Jian*, Zhiyong Xie, Lin Wang, Electromagnetohydrydynamic flow of Powell-Eyring fluids in a narrow confinement. Journal of Mechanics, 2017, 33, 225–233.
85. Mandula Buren, Yongjun Jian*, Long Chang, Fengqin Li, Quansheng Liu, Combined electromagneto- hydrodynamic flow in a microparallel channel with slightly corrugated walls, Fluid Dynamics Research, 2017, 49, 025517.
86. Mandula Buren, Yongjun Jian*, Long Chang, Quansheng Liu, Guangpu Zhao, AC magnetohydrodynamic slip flow in microchannel with sinusoidal roughness, Microsystem Technologies, 2017, 23, 3347–3359.
2016年
87. Fengqin Li, Yongjun Jian*, Long Chang, Guangpu Zhao, Liangui Yang, Alternating current electroosmotic flow in polyelectrolyte-grafted nanochannel, Colloids and Surfaces B: Biointerfaces 2016, 147, 234–241.
88. Guangpu Zhao, Yongjun Jian*, Fengqin Li, Streaming potential and heat transfer of nanofluids in parallel plate microchannels, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2016, 498, 239–247.
89. Guangpu Zhao, Yongjun Jian*, Fengqin Li, Heat transfer of nanofluids in microtubes under the effects of streaming potential, Applied Thermal Engineering, 2016, 100, 1299–1307.
90. Lin Wang, Yongjun Jian*, Quansheng Liu, Fengqin Li, Long Chang, Electromagnet hydrodynamic flow and heat transfer of third grade fluids between two micro-parallel plates, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2016, 494, 87–94.
91. Guangpu Zhao, Yongjun Jian*, Fengqin Li, Streaming potential and heat transfer of nanofluids in microchannels in the presence of magnetic field, Journal of Magnetism and Magnetic Materials, 2016, 407, 75–82.
92. Long Chang, Yongjun Jian*, Mandula Buren, Yanjun Sun, Electroosmotic flow through a microparallel channel with 3D wall roughness, Electrophoresis, 2016, 37(3), 482–492.
93. Dongqing Si, Yongjun Jian*, Long Chang, Quansheng Liu, Unsteady rotating electroosmotic flow through a slit microchannel, Journal of Mechanics, 2016, 32(5), 603–611.
94. Long Chang, Yongjun Jian*, Mandula Buren, Quansheng Liu, Yanjun Sun, Electroosmotic Flow Through a Microtube with Sinusoidal Roughness, Journal of Molecular Liquids, 2016, 220, 258–264.
95. Zhaodong Ding, Yongjun Jian*, Liangui Yang, Time periodic electroosmotic flow of micropolar fluids through a microparallel channel, Applied Mathematics and Mechanics (English Edition), 2016, 37(6), 769–786.
96. 邢靖楠，菅永军*，矩形纳米管道中的电动能量转换效率，应用数学和力学，2016, 37(4), 363–372.
97. 长龙，刘全生，菅永军*，布仁满都拉，孙艳军，具有正弦粗糙度的环形微管道中脉冲流动，应用数学和力学，2016, 37(10), 1118–1128.
98. 刘勇波，菅永军*，具有聚电解质层圆柱形纳米通道中的电动能量转换效率，物理学报，2016, 65(8), 084704.
99. Lin Wang, Yongjun Jian*, Fengqin Li, The flow of micropolar fluids through a corrugated microparallel channel, The European Physical Journal Plus, 2016, 131, 338.
100. Yufei, Wei, Haijun Wang, Yongjun Jian*, Pressure oscillating flow in corrugated parallel channel, Communications in Theoretical Physics, 2016, 66(6), 694–700.
2015年
101. Yongjun Jian*, Transient MHD heat transfer and entropy generation in a microparallel channel combined with pressure and electroosmotic effects, International Journal of Heat and Mass Transfer, 2015, 89, 193–205.
102. Yongjun Jian*, Long Chang, Electromagnetohydrodynamic (EMHD) micropumps under a spatially non-uniform magnetic field, AIP Advances, 2015, 5, 057121.
103. Yongjun Jian*, Dongqing Si, Long Chang, Quansheng Liu, Transient rotating Electromagnetohydrodynamic micropumps between two infinite microparallel plates, Chemical Engineering Science, 2015, 134, 12–22.
104. Yapeng Liu, Yongjun Jian*, Quansheng Liu, Fengqin Li, Alternating current magnetohydrodynamic electroosmotic flow of Maxwell fluids between two micro-parallel plates, Journal of Molecular Liquids, 2015, 211, 784–791.
105. Chonghua Gao, Yongjun Jian*, Analytical solution of magnetohydrodynamic flow of Jeffrey fluid through a circular microchannel, Journal of Molecular Liquids, 2015, 211, 803–811.
106. Guangpu Zhao, Yongjun Jian*, Long Chang, Mandula Buren, Magnetohydrodynamic flow of generalized Maxwell fluids in a rectangular micropump under an AC electric field,Journal of Magnetism and Magnetic Materials, 2015, 387, 111–117.
107. Mandula Buren, Yongjun Jian*, Electromagnetohydrodynamic (EMHD) flow between two transversely wavy microparallel plates, Electrophoresis, 2015, 36, 1539–1548.
108. Shunxiang Li, Yongjun Jian*, Zhiyong Xie, Quansheng Liu, Fengqin Li, Rotating electro-osmotic flow of third grade fluids between two microparallel plates, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2015,470, 240–247.
109. Dongqing Si, Yongjun Jian*, Electromagnetohydrodynamic (EMHD) micropump of Jeffrey fluids through two parallel microchannels with corrugated walls, Journal of Physics D: Applied Physic, 2015, 48, 085501.
2014年
110. Yongjun Jian*, Jie Su, Long Chang, Quansheng Liu, Guowei He, Transient electroosmotic flow of general Maxwell fluids through a slit microchannel, Z. Angew. Math. Phys. , 2014, 65, No. 3, 435- 447.
111. Mandula Buren; Yongjun Jian*; Long Chang, Electromagnetohydrodynamic flow through a micro- parallel channel with corrugated walls, Journal of Physics D: Applied Physics, 2014, 47, 425501.
112. Zhiyong Xie, Yongjun Jian*, Rotating electroosmotic flow of power-law fluids at high zeta potentials, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2014, 461, 231-239.
113. Long Chang, Yongjun Jian*, Jie Su, Ren Na, Quansheng Liu, Guowei He, Nonlinear interfacial waves in a circular cylindrical container subjected to a vertical excitation, Wave Motion, 2014, 51, 804-817.
2013年
114. Liping Bao, Yongjun Jian*, Long Chang, Jie Su, Haiyan Zhang, Quansheng Liu, Time periodic Electroosmotic flow of the generalized Maxwell fluids in a semicircular microchannel, Communications in Theoretical Physics, 2013, 59, 615-622.
115. Jie Su, Yongjun Jian*, Long Chang, Quansheng Liu, Transient electro-osmotic and pressure driven flows of two-layer fluids through a slit microchannel, Acta Mechanica Sinica, 2013, 29(4), 534–542.
116. Yanjun Sun, Yongjun Jian*, Long Chang, Quansheng Liu, Thermally fully developed electroosmotic flow of power-law fluids in a circular microchannel, Journal of Mechanics, 2013, 29(4), 609-616.
117. Lixia Sun, Yongjun Jian*, Long Chang, Haiyan Zhang, Quansheng Liu, Alternating current electro-osmotic flow of the Maxwell fluids through a circular micro-pipe, Journal of Mechanics, 2013, 29, 233-240.
2012年
118. Xiaoxia Li, Ze Yin, Yongjun Jian*, Long Chang, Jie Su, Quansheng Liu, Transient electro-osmotic flow of generalized Maxwell fluids through a microchannel, Journal of Non-Newtonian Fluid Mechanics, 2012, 187-188, 43–47.
119. Jie Su, Yongjun Jian*, Long Chang, Thermally fully developed electroosmotic flow through a rectangular microchannel, International Journal of Heat and Mass Transfer, 2012, 55, 6285–6290.
120. 长龙，菅永军*，平行板微管道间Maxwell流体的高Zeta势周期电渗流动，物理学报, 2012, 61 (12), 124702.
121. Shuyan Deng, Yongjun Jian*, Yuanhong Bi, Long Chang, Haijun Wang , Quansheng Liu, Unsteady electroosmotic flow of power-law fluid in a rectangular microchannel. Mechanics Research Communications, 2012, 39, 9–14.
2011年及以前
122. Quansheng Liu, Yongjun Jian*, Liangui Yang, Time periodic electroosmotic flow of the generalized Maxwell fluids between two micro-parallel plates, Journal of Non-Newtonian Fluid Mechanics, 2011, 166, 478–486.
123. Quansheng Liu, Yongjun Jian*, Liangui Yang, Alternating current electroosmotic flow of the Jeffreys fluids through a slit microchannel, Physics of Fluids, 2011, 23, 102001.
124. Yongjun Jian*, Quansheng Liu, Liangui Yang. AC electroosmotic flow of generalized Maxwell fluids in a rectangular microchannel, Journal of Non-Newtonian Fluid Mechanics, 2011, 166, 1304–1314.
125. Yongjun Jian*, Liangui Yang, Quansheng Liu, Time periodic electro-osmotic flow through a microannulus, Physics of Fluids, 2010, 22, 042001.
126. Jieshuo Xie, Yongjun Jian*, Liangui Yang, Strongly nonlinear internal soliton load on a small vertical circular cylinder in two-layer fluids, Applied Mathematical Modelling, 2010, 34, 2089–2101.
127. Yongjun Jian*, Qingyong Zhu, Jie Zhang, Yanfeng Wang, Third Order Approximation to Capillary Gravity Short Crested Waves with Currents, Applied Mathematical Modelling, 2009, 33, 2035–2053.
128. Yongjun Jian*, Jie Zhang, Quansheng, Liu, Yanfeng Wang, Effect of Mesoscale eddies on underwater sound propagation, Applied Acoustics, 2009, 70, 432–440.
129. Yongjun Jian*, Jiemin Zhan, Qingyong Zhu, Short crested wave–current forces around a large vertical circular cylinder, European Journal of Mechanics B/Fluids, 2008, 27(3), 346–360.
130. Yongjun Jian*, Xuequan E, Jie Zhang, Capillary effect on the vertically excited surface wave in a circular cylindrical vessel. Applied Mathematics and Mechanics (English Edition), 2006, 27(2), 227–234.
131. Yongjun Jian*, Xuequan E, Jie Zhang, Damping of vertically excited surface waves in a weakly viscous fluid. Applied Mathematics and Mechanics (English Edition), 2006, 27(3), 417–424.
132. Yongjun Jian*, Xuequan E, Instability Analysis of Nonlinear Surface Waves in a Circular Cylindrical Container Subjected to a Vertical Excitation. European Journal of Mechanics B/Fluids, 2005, 24(6), 683–702.
133. Yongjun Jian*, Xuequan E, Vertically forced surface wave in weakly viscous fluids bounded in a circular cylindrical vessel. Chinese Physics, 2004, 53(8), 1191–1200.
134. Yongjun Jian*, Xuequan E, Jie Zhang, Jun-min Meng, Surface waves in a vertically excited circular cylindrical container. Chinese Physics, 2004, 53(10), 1623–1630.
135. Yongjun Jian*, Xuequan E, Instability of the vertically forced surface wave in a circular cylindrical container. Chinese Physics, 2004, 53(10), 1631–1638.
136. Yongjun Jian*, Xuequan E, Jie Zhang, Junmin Meng, The effect of the surface tension of the mode selection of the vertically excited surface wave in a circular cylindrical vessel. Chinese Physics, 2004, 53(12), 2013–2020.
137. Yongjun Jian*, Xuequan E, Liulin Feng, Surface wave patterns and instability in a vertically oscillating circular cylindrical vessel，Journal of Hydrodynamics, Ser. B, 2004, 16(5), 640– 645.
138. 菅永军*，鄂学全，刚性充液容器内竖直激励表面波研究进展，力学进展，2004, 34(1), 61–76.
139. Jian Yongjun*, E Xuequan, Bai Wei, Nonlinear Faraday waves in a parametrically excited circular cylindrical container. Applied Mathematics and Mechanics (English Edition), 2003, 24(10), 1194–1207.
140. 菅永军*，鄂学全，垂直激励圆柱形容器中的表面波特性研究，应用力学学报, 2004, 21(1), 5-12.
141. 菅永军*，鄂学全，垂直激励圆柱形容器中的表面波结构，水动力学研究与进展 A辑，2003, 18(2), 135-147.

代表性专利&其他
1. 2019年获内蒙古自治区“草原英才”工程个人滚动支持。
2. 2018年获第八届内蒙古大学校长励学奖优秀教师奖；
3. 2017年内蒙古自治区新世纪“321人才工程”第一层次人选；
4. 2016年获内蒙古自治区优秀科技工作者；
5. 2016年获宝钢优秀教师奖；
6. 2015年入选内蒙古自治区第五批“草原英才”；
7. 2014年获内蒙古自治区优秀研究生指导教师；
8. 2013年内蒙古自治区高等学校“青年科技领军人才”获得者；
9. 2012年内蒙古自治区新世纪“321人才工程”第二层次人选；
10. 2010年获内蒙古自治区自然科学奖三等奖、内蒙古大学第五届科学技术创新奖；
11. 2009年获第七届内蒙古自治区青年科技奖；

菅永军

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