杨光 - 上海交通大学 - 机械与动力工程学院

个人简介

教育背景 2011.09-2016.06 上海交通大学动力工程及工程热物理博士 2007.09-2011.07 天津大学建筑环境与设备工程学士工作经历 2021- 至今上海交通大学机械与动力工程学院副教授、博导 2019-2020 上海交通大学机械与动力工程学院助理教授、博导 2016-2018 斯图加特大学航天热力学研究所 Research Associate 出访及挂职经历 2016.12-2019.01 斯图加特大学航天热力学研究所 2019.11-2019.11 斯坦福大学机械工程系课题交流科研项目主持项目： 2023-2026 国家自然科学基金（面上项目） 2022-2024 上海市自然科学基金 2021-2024 JKW-JCJQ重点基础研究项目课题 2021-2022 中国商飞大飞机创新谷研究计划项目 2020-2021 上海航天先进技术联合研究基金 2020-2022 国家自然科学基金（青年项目） 2019-2022 航天低温推进剂技术国家重点实验室开放课题 2019-2022 空间飞行机构重点实验室开放课题（2项） 2019-2021 浦江人才计划项目 2016-2018 博士后创新人才支持计划 2016-2018 博士后科学基金项目 2019-2021 上海交通大学双一流建设项目主持多项航空航天、船舶海洋领域工程项目主要参与: 2020-2024 国家自然科学基金（重点项目） 2018-2025 德国科学基金会重点研究项目SFB1313 教学工作低温技术及其应用本科生 32学时云计算技术致远荣誉计划本科生 32学时程序设计思想与方法（C++）工科平台本科生 80学时持续指导毕业设计、大创、PRP、本科生科研实习项目。软件版权登记及专利一种宽温域低温环境试验装置一种反重力液体获取实验装置一种用于研究多孔结构中气体流动特性的实验装置, 一种湍流混合对流传热实验装置蒸汽输送管道沿途冷凝水回收装置一种高低温常压热循环试验装置用于大型高低温环境试验箱的外门启闭结构一种大型高低温保温箱体荣誉奖励 2023 上海交通大学聘期考核“优秀” 2021 机械与动力工程学院“最受欢迎教师奖” 2021 机械与动力工程学院教学竞赛三等奖 2021 “莙政学者”--指导教师 2020 全国大学生节能减排大赛三等奖 --指导教师 2019 上海市浦江人才计划 2016 国家博士后创新人才支持计划 2016 上海市科技进步一等奖 2016 上海市优秀毕业生 2015 博士研究生国家奖学金 2018 "International Journal of Heat and Mass Transfer", Outstanding Reviewer 2018 最佳墙报奖, 30th GCCCD Annual Conference

研究领域

低温多相流动与传热；低温推进剂在轨贮存与管理；航天航空热环境模拟与控制；多孔介质流动及传热传质; 先进热管理技术

近期论文

查看导师最新文章（温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

已录用: [65]杨恩博,金宇鹏,杨光,黄永华,王天祥,雷刚,吴静怡.内角钝度对微重力下液体推进剂毛细流动特性的影响[J/OL].上海交通大学学报, 2022 [64]陈燕地,张婉雨,张良俊,李春煜,吴静怡,杨光.侧风道对多孔保温材料内水分迁移特性的影响规律研究[J/OL].真空与低温, 2022 [63]王晔,杨光,金鑫,耑锐,任枫,汪彬,吴静怡, 网幕通道式液体获取装置相分离特性低温实验.航空动力学报, 2022 2023： 62. 李嘉,张良俊,吴仕泽,李晓慈,蔡爱峰,杨光,吴静怡.基于模糊PID的低温环境试验系统控制特性研究[J/OL].真空与低温, 2022, 29, 180-187 2022: 61. M. Xiao, G. Yang, Y. Huang, J. Wu, Evaluation of different interface-capturing methods for cryogenic two-phase flows under microgravity, Physics of Fluids, 34:112124 60. X. Zhou, G. Yang, C. Li*, J. Wu. Functional microdroplet self-dislodging icephobic surfaces: a review from mechanism to synergic morphology. Applied Thermal Engineering, 2022: 118928. 59. Z. Wang, G. Yang*, Y. Wang, et al. A three-dimensional flow model of screen channel liquid acquisition devices for propellant management in microgravity.npj Microgravity, 2022, 8: 28. 58. G. Yang, R. Xu, Y. Wang, et al. Pore-scale numerical simulations of flow and convective heat transfer in a porous woven metal mesh. Chemical Engineering Science, 2022: 117696. 57. X. Cheng, G. Yang*, J. Wu. Spontaneously grown boehmite structures improve pool boiling heat transfer on aluminium surfaces. International Journal of Heat and Mass Transfer, 2022, 192: 122937. 56. T. Yi, G. Yang*, B. Wang, R. Zhuan, Y. Huang, J. Wu, Dynamics of a gas bubble penetrating through porous media, Physics of Fluids, 2022, 34, 012103 55. Y. Wang, Z. Wang, X. Cheng, G. Yang*, J. Wu. Pressure-Driven Phase Separation Based on Modified Porous Mesh for Liquid Management in Microgravity. Langmuir, 2022, 38, 9, 2919–2927 54. T. Yi, X. Chu, B. Wang, J. Wu, G. Yang*, Numerical simulation of single bubble evolution in low gravity with fluctuation, International Communications in Heat and Mass Transfer, 2022, 130, 105828. 53. Y. Wang, J. Wu, G. Yang*, Numerical simulation of heat and momentum transport at the coupled interface between a rectangular channel and porous media, Journal of Thermal Science, 2022, 31, 332–343. 52. 王峥,王晔,金鑫,张浩,汪彬,耑锐,杨光,吴静怡.网幕通道式液体获取装置的入口速度分布特性研究[J].真空与低温,2022,28(05):556-564. 51. 王晔,张婉雨,汪彬,耑锐,任枫,蔡爱峰,杨光,吴静怡.多孔网幕泡破压力预测模型的建立及实验验证[J].化工学报,2022,73(03):1102-1110. 50. 聂晓展,程鑫,王珊珊,李春煜,杨光,吴静怡.大面积超薄蒸汽腔力学特性仿真分析[J].系统仿真技术,2022,18(04):233-239. 49. 金宇鹏,肖明堃,邱一男,王天祥,杨光,黄永华,吴静怡.基于磁补偿实验的微重力下毛细管内动态流动特性研究[J].力学学报,2022,54(12):3408-3417. 48. 易天浩,杨光,黄永华,吴静怡.基于扩散界面法的微重力下液氢沸腾传热研究[J].工程热物理学报,2022,43(09):2494-2500. 47. 杨光,程鑫,王峥,王晔,张良俊,吴静怡.微纳多孔结构中稀薄气体流动渗透率的解析型预测模型[J].化工学报,2022,73(07):2895-2901. 46. 杨光,张良俊,张婉雨,陈燕地,杜懿岑,吴静怡.常压低温环境下抛物面薄壁结构热平衡特性分析[J].真空与低温,2022,28(03):333-340. 2021: 45. G. Yang, J. Liu, X. Cheng, Y. Wang, ... , R.A. Fischer. A superhydrophilic metal–organic framework thin film for enhancing capillary-driven boiling heat transfer. Journal of Materials Chemistry A,2021,9, 25480-25487 44. K. Yang, G. Yang, and J. Wu, Quantitatively Understanding the Insights into CO2 Adsorption on Faujasite from the Heterogeneity and Occupancy Sequence of Adsorption Sites. The Journal of Physical Chemistry C, 2021, 125, 28, 15676–15686 43. J. Wu, R. Lv, Y. Huang, G. Yang, Flow Structure Transition and Hysteresis of Turbulent Mixed Convection Induced by a Transverse Buoyant Jet, International Journal of Heat and Mass Transfer, 2021, 177, 121310 42. J. Wu, R. Lv, Y. Huang, G. Yang, Transverse buoyant jet-induced mixed convection inside a large thermal cycling test chamber with perforated plates. International Journal of Thermal Sciences, 2021, 168, 107080. 41. W. Li,# G. Yang,#* A. Terzis, S. Mukherjee, C. He, X. An, J. Wu, B. Weigand, R.A. Fischer,* In Situ Tracking of Wetting‐Front Transient Heat Release on a Surface‐Mounted Metal-Organic Framework. Advanced Materials, 2021, 2006980. 40. Y. Wang, Y. Lin, G. Yang*, J. Wu, Flow Physics of Wicking into Woven Screens with Hybrid Micro-/Nanoporous Structures. Langmuir, 2021, 37, 7, 2289–2297, Supplementary Cover Article 39. X. Cheng, G. Yang*, J. Wu, Recent advances in the optimization of evaporator wicks of vapor chambers: From mechanism to fabrication technologies. Applied Thermal Engineering, 188 (2021) 116611 38. Y. Wang, G. Yang*, Y. Huang, Y. Huang, R. Zhuan, J. Wu. Analytical model of flow-through-screen pressure drop for metal wire screens considering the effects of pore structures. Chemical Engineering Science, 2021, 116037: doi.org/10.1016/j.ces.2020.116037 37. K. Yang, G. Yang, and J. Wu, Insights into the enhancement of CO2 adsorption on faujasite with a low Si/Al ratio: Understanding the formation sequence of adsorption complexes. Chemical Engineering Journal, 404, 2021, 127056 36. W. Wang, G.Yang, C. Evrim, A. Terzis, R. Helmig, X. Chu, An assessment of turbulence transportation near regular and random permeable interfaces. Physics of Fluids, 2021, 33(11), 115103. 35. 杨凯中,杨光,吴静怡.不同阳离子分子筛中CO2吸附结构形成与变化机理[J].真空与低温,2021,27(06):535-542. 2020: 34. X. Chu, W. Wang, G. Yang, A. Terzis, R. Helmig, B. Weigand. Transport of Turbulence Across Permeable Interface in a Turbulent Channel Flow: Interface-Resolved Direct Numerical Simulation. Transport in Porous Media, 2020, doi.org/10.1007/s11242-020-01506-w 33. K. Weishaupt, A. Terzis, I. Zarikos, G. Yang, B. Flemisch, D.A.M. de Winter, R. Helmig. A Hybrid-Dimensional Coupled Pore-Network/Free-Flow Model Including Pore-Scale Slip and Its Application to a Micromodel Experiment. Transport in Porous Media, 2020. doi.org/10.1007/s11242-020-01477-y 32. X. Chu*, Y. Liu, W. Wang, G. Yang*, B. Weigand, H. Nemati, Turbulence, pseudo-turbulence and local flow topology in dispersed bubbly flow, Physics of Fluids, 32, 083310 (2020); doi.org/10.1063/5.0014833 31. G. Yang, X. Chu, V. Vaikuntanathan, S. Wang, J. Wu, B. Weigand, and A. Terzis, Droplet mobilization at the walls of a microfluidic channel, Physics of Fluids, 32, 012004 (2020), Editor's pick 30. K. Yang, J. Wu, C. Li, Y. Xiang, G. Yang, Efficient Method to Obtain the Force Field for CO2 Adsorption on Zeolite 13X: Understanding the Host–Guest Interaction Mechanisms of Low-Pressure Adsorption, The Journal of Physical Chemistry C , 2019, 124(1): 544-556. 29. 杜懿岑,程睿杰,吴仕泽,蔡爱峰,吴静怡,杨光.低温非热平衡圆柱温度分布特性的数值分析与实验[J].制冷学报,2020,41(06):109-116. 28. 肖明堃,黄永华,吴静怡,杨光,耑锐.非均匀磁场力作用下微重力液氧气液界面特性[J].制冷技术,2020,40(06):1-11. 2019： 27. G. Yang, A. Terzis, I. Zarikos, S. M. Hassanizadeh, B. Weigand, R. Helmig, Internal flow patterns of a droplet pinned to the hydrophobic surfaces of a confined microchannel using micro-PIV and VOF simulations, Chemical Engineering Journal, 2019, 370: 444-454 26. A. Terzis, I. Zarikos, K. Weishaupt, G. Yang, X. Chu, R. Helmig, B. Weigand, Microscopic velocity field measurements inside a regular porous medium adjacent to a low Reynolds number channel flow, Physics of Fluids 2019, 31, 4, 042001 25. X. Chu, G. Yang, S. Pandy, B. Weigand, Direct numerical simulation of convective heat transfer in porous media, International Journal of Heat and Mass Transfer, 2019,133 :11-20 24. G. Yang, E. Coltman, K. Weishaupt, et al. On the Beavers–Joseph Interface Condition for Non-parallel Coupled Channel Flow over a Porous Structure at High Reynolds Numbers. Transport in Porous Media, 2019: 1-27. 23. Y.Y. Huang, G. Yang, and J. Y. Wu. Large eddy simulation and experimental study of turbulent mixed convection inside a cavity with large Rayleigh number: Effect of buoyancy. Building and Environment 2019, 151:268-279 22. G. Yang, V. Vaikuntanathan, A. Terzis, et al. Impact of a Linear Array of Hydrophilic and Superhydrophobic Spheres on a Deep Water Pool. Colloids and Interfaces, 2019, 3(1): 29. 21. 陈亮,杨光,邹红菲,马建章.从效用视角审视人工树洞的研究与设计[J].林业科学,2019,55(03):141-148. 20. 陈国珍,吴静怡,杨光,黄一也.耦合传热下低温柱体温度均匀性的优化分析[J].低温与超导,2018,46(08):6-11 2018： 19. G. Yang, B. Weigand, Investigation of the Klinkenberg effect in a micro and nanoporous medium by direct simulation Monte Carlo method, Physical Review Fluids, 2018, 3(4) :044201 18. G. Yang, B. Weigand, A. Terzis, et al. Numerical simulation of turbulent flow and heat transfer in a three-dimensional channel coupled with flow through porous structures, Transport in Porous Media, 2018, 122-145 17. G. Yang, L. Zhang, Wu J, et al. Analysis of transient temperature field characteristics inside a large-scale thermal cycling test cavity for spacecraft. Heat Transfer Research, 2018, 49 : 255–273 16. L. Zhang, Y. Huang, G. Yang*, J.Y. Wu. Numerical Simulation of Conjugate Turbulent Mixed Convection in an Open Cavity : Evaluation of Different Wall Heat Conduction Models. Numerical Heat Transfer, Part A : Applications, 2018, 74, 1244-1264 15. A. Terzis, G. Yang, I. Zarikos, et al. A temperature-based diagnostic approach for paper-based microfluidics. Microfluidics and Nanofluidics, 2018, 22(3) : 35 14. A. Terzis, E. Sauer, G. Yang et al. Characterisation of acid–base surface free energy components of urea–water solutions. Colloids and Surfaces A : Physicochemical and Engineering Aspects, 2018, 538 : 774-780 13. L. Zhang, Y. Huang, J.Y. Wu, Z. Liu, G. Yang. Evaporation of water film in a three-dimensional vertical rectangular channel by laminar mixed convection. Applied Thermal Engineering, 2018, 130(5) :242-253 12. L. Zhang, Z. Liu, J.Y. Wu, G. Yang, M. Bao. Computational investigation on nitrogen displacement process in a thermal environment simulation chamber.Science and Technology for the Built Environment, 2018, 24(4) : 343-355 2017： 11. G. Yang, Y.Y. Huang, J.Y. Wu, Experimental study and numerical models assessment of turbulent mixed convection heat transfer in a vertical open cavity, Building and Environment, 2017, 115 : 91-103 10. Y. Huang, L. Zhang, G. Yang, J.Y. Wu. Secondary flow and entropy generation of laminar mixed convection in the entrance region of a horizontal square duct. ASME Journal of Heat Transfer. 2017,140(3) :034503 2016： 9. G. Yang, J.Y. Wu. Effects of natural convection, wall thermal conduction and thermal radiation on the heat transfer uniformity at a heated plate located at the bottom of a three dimensional rectangular enclosure, Numerical Heat Transfer, Part A : Applications, 2016, 69 : 589-606 8. 黄一也, 杨光, 吴静怡. 以最佳温度均匀度和最小熵产为目标的航天器热循环试验系统运行参数优化. 化工学报,2016, 10 : 4086-4094 2015： 7. G. Yang, J.Y. Wu. Conjugate mixed convection in the entrance region of a symmetrically heated vertical channel with thick walls. International Journal of Thermal Sciences, 2015, 98 : 245-254 6. G. Yang, J.Y. Wu. Entropy generation in a rectangular channel of buoyancy opposed mixed convection. International Journal of Heat and Mass Transfer, 2015, 86 : 809-819 2014： 5. G. Yang, J.Y. Wu. Effect of aspect ratio and assisted buoyancy on flow reversal for mixed convection with imposed flow rate in a vertical three dimensional rectangular duct. International Journal of Heat and Mass Transfer, 2014, 77 : 335-343 4. 杨光, 吴静怡. 三维动态混合对流过程中的温度均匀性分析及实验验证. 工程热物理学报, 2014, 35 : 730-734 3. 杨光, 吴静怡. 基于小波变换和多元回归的航天器热循环试验系统温度均匀性分析. 上海交通大学学报, 2014, 48 :1346-1350 2013： 2. G. Yang, J.Y. Wu, L. Yan. Flow reversal and entropy generation due to buoyancy assisted mixed convection in the entrance region of a three dimensional vertical rectangular duct. International Journal of Heat and Mass Transfer, 2013, 67 : 741-751 1. G. Yang, J.Y. Wu. Effect of Side ratio and aiding/opposing buoyancy on the aerodynamic and heat transfer characteristics around a rectangular cylinder at low Reynolds numbers. Numerical Heat Transfer, Part A : Applications, 2013, 64 : 1016-1037 会议论文： 14. G. Yang, X. Chu, B. Weigand, R. Helmig. Turbulence transport across the coupled interface between porous media and free flow: A pore-scale analysis. Interpore 2020. (Invited Talk) 13. G. Yang. Internal Fluidity of a Droplet Pinned to the Hydrophobic Surfaces of a Confined Microchannel, ASME 2019 International Mechanical Engineering Congress & Exposition, Salt Lake City, USA 12. Weigand, B., Chu, X., Yang, G., & Helmig, R. Numerical simulations of turbulent flow and heat transfer in regular porous structures. Keynote Speech at InterPore 2019, Valencia, Spain 11. G. Yang. On the Beavers–Joseph Interface Condition for Non-parallel Coupled Channel Flow over a Porous Structure at High Reynolds Numbers. SFB1313 Status Seminar, Blaubeuren, Germany, 2019 10. G. Yang, B. Weigand, A hybrid DSMC/Navier-Stokes framework to solve the coupled channel flow and rarefied porous media flow.2nd International Conference on Simulation Technology, Stuttgart, Germany, 2018 (Invited Talk) 9. G. Yang, A. Terzis, I. Zarikos, et al., Droplet motion in a microfluidic channel under the effect of contact angle hysteresis. 30th GCCCD Annual Conference, Karlsruhe, Germany, 2018 (Best Poster Award) 8. G. Yang, V. Vaikuntanathan, A. Terzis, B. Weigand, R. Helmig, Impact of a linear array of hydrophilic and superhydrophobic spheres on water pool, Gallary of Fluid Motion, 71th Annual Meeting of the APS Division of Fluid Dynamics, 2018 7. G. Yang, Simulation of gas diffusion in porous materials consisting of micro-/nanoscale structures, Applied Nanotechnology and Nanoscience International Conference, Rome, Italy, 2017 6. K. Weishaupt, A. Terzis, I. Zarikos, G. Yang, et al. Using a pore-network model to couple mass,momentum and energy at the interface between free flow and porous media flow. 9th International Conference on Porous Media, Rotterdam, Netherlands 2017 5. Y. Huang, G. Yang, J.Y. Wu. Mixed convection characteristic inside a thermal cycling chamber with nonuniform perforated plate. Proceedings of the ASME 2016 International Mechanical Engineering Congress & Exposition,Phoenix, USA 4. G. Yang, J.Y. Wu, Y.W. He, L. Yan, Investigation of temperature uniformity in an open cavity of buoyancy assisted mixed convection heat transfer with multiple discrete inlet and outlet ports, Proceedings of the ASME 2014 International Mechanical Engineering Congress & Exposition, Montreal, Canada 3. G. Yang, J.Y. Wu. Investigation of the steady-state temperature field characteristics inside a thermal cycling test chamber of turbulent mixed convection. 24th International Congress of Refrigeration, Yokohama, Japan, 2015 2. G. Yang, J.Y. Wu, Y.X. Xu, S.C. Yang, L. Yan, Analysis of temperature uniformity in the cooling/heating process of transient turbulent mixed convection, 15th Cross Strait Symposium on Energy and Environmental Science and Technology, Shanghai, China, 2014 1. G. Yang, J.Y. Wu, L.J. Zhang, Design and simulation of a novel accelerated thermal cycling test system for space application, Cryogenics and Refrigeration Proceedings of ICCR’2013, Hangzhou, China

学术兼职

《真空与低温》青年编委；《系统仿真学报》青年编委； InterPore会员； ASME会员； GCCCD会员担任以下学术期刊审稿人： Physics of Fluids, International Journal of Thermal Sciences, International Journal of Heat and Mass Transfer, Transport in Porous Media, Journal of Heat Transfer, Building and Environment, Experimental Thermal and Fluid Science, Science and Technology for the Built Environment, Experimental Heat Transfer, Journal of Computational Physics, Engineering Science and Technology, Journal of Applied and Computational Mechanics, Chinese Journal of Chemical Engineering......