2011.09-2016.06 上海交通大學(xué) 動(dòng)力工程及工程熱物理 博士
2007.09-2011.07 天津大學(xué) 建筑環(huán)境與設(shè)備工程 學(xué)士

2021-至今 上海交通大學(xué) 機(jī)械與動(dòng)力工程學(xué)院 副教授/長(zhǎng)聘副教授、博導(dǎo)

2019-2020 上海交通大學(xué) 機(jī)械與動(dòng)力工程學(xué)院 助理教授、博導(dǎo)

2016-2018 斯圖加特大學(xué) 航天熱力學(xué)研究所 Research Associate

低溫多相流動(dòng)與傳熱；
低溫推進(jìn)劑在軌貯存與管理；
多孔介質(zhì)流動(dòng)及傳熱傳質(zhì);
航天航空熱環(huán)境模擬；
先進(jìn)熱管理技術(shù)

國(guó)際制冷學(xué)會(huì)A1(低溫)專業(yè)委員會(huì) 青年委員
上海制冷學(xué)會(huì) 理事、青委會(huì)委員
船舶與海洋工程特種裝備和動(dòng)力系統(tǒng)國(guó)家工程研究中心-制冷與低溫工程檢測(cè)實(shí)驗(yàn)室，主任
《真空與低溫》、《制冷學(xué)報(bào)》、《Carbon Neutrality》期刊，青年編委
《International Journal of Heat and Mass Transfer》期刊，Guest Editor
《Physics of Fluids》期刊，Guest Editor

擔(dān)任以下學(xué)術(shù)期刊審稿人：
PNAS, Advanced Materials, 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......

主持項(xiàng)目：

2023-2026 國(guó)家自然科學(xué)基金：基于微納雙級(jí)多孔結(jié)構(gòu)毛細(xì)力調(diào)控的低溫兩相流體選擇性輸運(yùn)機(jī)理研究

2026-2026 中國(guó)航天基金會(huì)空天動(dòng)力基金重點(diǎn)項(xiàng)目，低溫推進(jìn)劑在軌熱力學(xué)特性研究

2025-2026 航天器熱控全國(guó)重點(diǎn)實(shí)驗(yàn)室開放基金，低溫工質(zhì)氣液分離

2023-2024 航天科研項(xiàng)目：低溫推進(jìn)劑在軌管理仿真系統(tǒng)

2023-2025 工信部高技術(shù)船舶科研項(xiàng)目，陸上LNG低溫工程試驗(yàn)驗(yàn)證技術(shù)研究，子課題負(fù)責(zé)人

2023-2025 工信部高技術(shù)船舶科研項(xiàng)目，自主薄膜型圍護(hù)系統(tǒng)研制，子課題負(fù)責(zé)人

2024-2025 中國(guó)科學(xué)院微重力重點(diǎn)實(shí)驗(yàn)室開放課題，低溫微重力實(shí)驗(yàn)

2022-2024 上海市自然科學(xué)基金: 基于毛細(xì)輸運(yùn)-力學(xué)承載雙效結(jié)構(gòu)陣列的薄壁蒸汽腔傳熱機(jī)理研究與性能優(yōu)化

2020-2022 上海航天先進(jìn)技術(shù)聯(lián)合研究基金：低溫毛細(xì)流體管理技術(shù)研究

2020-2022 國(guó)家自然科學(xué)基金：基于混合潤(rùn)濕性多孔結(jié)構(gòu)的毛細(xì)流動(dòng)-蒸發(fā)傳熱耦合機(jī)理研究 （結(jié)題評(píng)價(jià)“優(yōu)秀”）

2019-2022 航天低溫推進(jìn)劑技術(shù)國(guó)家重點(diǎn)實(shí)驗(yàn)室開放課題：地面模擬微重力環(huán)境下的表面張力流動(dòng)實(shí)驗(yàn)與仿真研究

2021-2022 中國(guó)商飛大飛機(jī)創(chuàng)新谷研究計(jì)劃項(xiàng)目

2021-2022 篩網(wǎng)特性試驗(yàn)技術(shù)研究

2022-2022 液氫船相關(guān)研究

2019-2022 空間飛行機(jī)構(gòu)重點(diǎn)實(shí)驗(yàn)室開放課題（2項(xiàng)）

2019-2021 浦江人才計(jì)劃項(xiàng)目

2016-2018 博士后創(chuàng)新人才支持計(jì)劃

2016-2018 博士后科學(xué)基金項(xiàng)目

2019-2021 上海交通大學(xué)雙一流建設(shè)項(xiàng)目

主要參與:
2020-2024 國(guó)家自然科學(xué)基金（重點(diǎn)項(xiàng)目）：低溫推進(jìn)劑在軌狀態(tài)的熱力學(xué)機(jī)理研究
2018-2025 德國(guó)科學(xué)基金會(huì)重點(diǎn)研究項(xiàng)目SFB1313：Interface-Driven Multi-Field Processes in Porous Media – Flow, Transport and Deformation

2026:

80. Q. Cao, X. Zhang, S. Lu, J. Wang, S. Guo, G. Tabor, J. Wu, X. Chu, G. Yang. Integrating data and physics: A review of data-driven methods for computational multiphase flow. Chemical Engineering Journal, 2026: 173311.

79. M. Xiao, Y. Huang, G. Yang, C. Li, A. Cai, J. Wu. Influencing mechanism of the non-isothermal behavior of an isolated vapor bubble in liquid oxygen. Cryogenics, 2026: 104292.

78. S. Guo, M. Xiao, L. Yue, Q. Cao, W. Du, L. Chen, J. Zhao, W. Dai, G. Yang, J. Wu. On the liquid layer formation and thermodynamic behavior of liquid oxygen during interface reorientation: A combined drop tower experiment and simulation study. Energy, 2025: 139721.

77. S. Chen, R. Zhuan, J. Wang, S. Guo, Z. Jiang, W. Luo, J. Wu, G. Yang, Enhancement of cryogenic quenching heat transfer by nanoscale boehmite structures on aluminum surfaces, International Journal of Heat and Mass Transfer, 2026, 256, 127989

76. M. Xiao, Y. Huang, G. Yang, C. Li, A. Cai, J. Wu, Bubble detachment dynamics in cryogenic boiling under microgravity: Experiments and empirical models, International Journal of Heat and Mass Transfer, 2026, 256, 127915

75. Y. Tian, C. Li, G. Yang, M. Xiao, A. Cai, J. Wu. Effects of geometric features on the diffusion and heat transfer behavior of vapor on a passive anti-frosting surface. International Journal of Heat and Mass Transfer, 2026, 257: 128233.

2025：

74. R. Xu, W. Miao, M. Xiao, Q. Cao, Y. Huang, J. Wu, G. Yang. Experimental study of liquid–vapor separation of cryogenic propellants under a ground-based magnetic compensation microgravity environment. Cryogenics, 2025, 152, 104232.

73. G. Yang, B. Yang, W. Luo, X. Cheng, M. Jiang, C. Li, X. Qian, X. Chu, J. Wu, High-efficiency thermal diodes enabled by unidirectional capillary fluid transport and phase change, Cell Reports Physical Science, 2025, 6(9), 102793

72. H. Li, H. Chen, Y. Wang, Z. Zuo, H. Wang, J. Wu, G. Yang, Resolving the rollover challenges in liquefied natural gas storage: A review from mechanism studies to advanced predictive approaches, Applied Thermal Engineering, 2025, 281, 128551

71. J. Wang, M. Xiao, H. Shao, A. Cai, G. Yang, J. Wu, Nucleate boiling of liquid oxygen under a magnetically compensated reduced-gravity environment, Applied Thermal Engineering, 2025, 128584

70. M. Xiao, J. Wang, Y. Huang, G. Yang, A. Cai, R. Zhuan, H. Tang, X. Guo, J. Wu, Stable long-term ground-based microgravity environment for cryogenic fluids, Device, 2025, 100869

69. B. Yang, X. Chu, Y. Wang, J. Wu, G. Yang; Capillary-driven liquid transport in a multistage micropillar array. Physics of Fluids, 2025; 37 (4): 042119

68. C. Chen, W. Miao, R. Xu, Y. Wang, J. Wu, G. Yang; Theoretical and Numerical Study of Bubble Blocking in Wetted Hierarchical Porous Structures.  Microgravity Science and Technology, 2025, 37, 23

67. R. Xu, C. Chen, B. Wang, W. Miao, M. Zhang, J. Wu, G. Yang; Experimental study of bubble flow dynamics in an asymmetric hierarchical porous structure. Physics of Fluids, 2025; 37 (2): 022120

66. S. Guo, Z. Jiang, J. Li, P. Xu, R. Zhuan, M. Xiao, Q. Cao, J. Zhao, G. Yang, J. Wu, Numerical investigation on helium pressurization behavior of cryogenic propellant in microgravity. Applied Thermal Engineering, 2025, 269, 125926

65. P. Xu, H. Chen, W. Shi, Y. Jin, H. Wang, A. Cai, C. Li, J. Wu, G. Yang, Experimental study of cryogenic fluid flow through fibrous porous media, Energy, 2025, 315, 134358

64. H. Chen, T. Wu, Z. Wan, H. Wang, P. Xu, G. Yang, J Wu, Numerical analysis of LNG rollover in large membrane tank under sloshing excitations, Energy, 2025, 315, 134351

63. M. Xiao, Y. Huang, G. Yang, C. Li, A. Cai, J. Wu, Visualization of cryogenic bubble growth in liquid oxygen during nucleate pool boiling, Energy, 2025, 314, 134101

62. H. Chen, P. Xu, Z. Wan, W. Song, G. Yang, J. Wu. Analysis of convection and boil-off in multi-scale membrane LNG tanks under sloshing excitations. Applied Thermal Engineering, 2025, 259: 124863.
61. R. Lv, S. Guo, Y. Huang, G. Yang, J. Wu. Evaluation of thermal destratification performance and optimization of jetting parameters in a spray-bar thermodynamic vent system. Applied Thermal Engineering, 2025, 258: 124621.

2024:
60. G. Yang, R. Xu, Y. Tian, S. Guo,J. Wu, X. Chu. Data-driven methods for flow and transport in porous media: A review. International Journal of Heat and Mass Transfer, 2024, 235, 126149.
59. X. Zhang, Y. Liu, W. Wang, G. Yang, X. Chu; An investigation of anisotropy in the bubbly turbulent flow via direct numerical simulations.  Physics of Fluids, 2024; 36 (9): 093348

58. W. Zhang, J. Wu, G. Yang, Conduction-convection coupled heat transfer around a hollow cylinder under different buoyancy forces. Chinese Journal of Aeronautics, 2024, 37, 216-228

57. X. Zhou, Z. Hu, R. Lv, S. Guo, C. Li, G. Yang, J. Wu, Behaviors of microdroplets impinging on supercooled superhydrophobic microgrooves, Physics of Fluids, 2024, 36, 122113
56. M. Xiao, G. Yang, Y. Huang, C. Li, A. Cai, J. Wu. CryoFoam: A practical numerical framework for non-isothermal two-phase flows in cryogenic fluids with phase change. International Journal of Hydrogen Energy, 2024, 80, 871-889.
55. X. Zhou, et al. Inter-droplet frosting propagation mechanism on micropillar patterned surfaces under various supersaturation conditions. Colloids and Surfaces A, 2024, 699: 134761.
54. S. Guo, M. Xiao, F. Xie, Y. Ma, K. Chen, R. Zhuan, G. Yang, J. Wu, Optimization of helium consumption for feedback pressurization in liquid oxygen tanks, International Journal of Heat and Mass Transfer, 2024, 230: 125739
53. G. Yang, B. Yang, X. Cheng, S. Wang, C. Li, G. Liu, J. Wu, Aluminum micropillar wicks integrated with boehmite nanostructures for rapid heat dissipation, International Journal of Heat and Mass Transfer, 2024, 223: 125211
52. Y. Liu, X. Chu, G. Yang, B. Weigand, Simulation and analytical modeling of high-speed droplet impact onto a surface, Physics of Fluids, 2024, 36, 012137

2023：
51. T. Yi, W. Zhang, Y. Qiu, G. Lei, Y. Yu, J. Wu, G. Yang, Effect of physical properties on the dynamics of an isolated bubble squeezing through a narrow constriction, International Journal of Multiphase Flow, 169, 2023, 104601
50. G. Hou, ..., X. Qian, Self-regulated underwater phototaxis of a photoresponsive hydrogel-based phototactic vehicle, Nature Nanotechnology, 2024, 19, 77–84
49. Y. Liu, W. Wang, G. Yang, H. Nemati, X. Chu; The interfacial modes and modal causality in a dispersed bubbly turbulent flow. Physics of Fluids, 2023, 35, 083309

48. Z. Liu, J. Wu, G. Yang, et al. A numerical study of COVID-19-laden droplets dispersion in aircraft cabin ventilation system. Heliyon, 2023, 9(3), e13920

47. H. Chen, G. Yang, J. Wu. A multi-zone thermodynamic model for predicting LNG ageing in large cryogenic tanks. Energy, 2023, 128503.

2022:
46. M. Xiao, G. Yang, Y. Huang, J. Wu, Evaluation of different interface-capturing methods for cryogenic two-phase flows under microgravity, Physics of Fluids, 2022, 34, 112124
45. 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.
44. 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.
43. 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.
42. 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.
41. 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
40. 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
39. 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.
38. 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.

2021:
37. 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
36. K. Yang, G. Yang, and J. Wu, Quantitatively Understanding the Insights  CO2 Adsorption on Faujasite from the Heterogeneity and Occupancy Sequence of Adsorption Sites. The Journal of Physical Chemistry C, 2021, 125, 28, 15676–15686
35. 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
34. 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.
33. 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.
32. Y. Wang, Y. Lin, G. Yang, J. Wu, Flow Physics of Wicking  Woven Screens with Hybrid Micro-/Nanoporous Structures. Langmuir, 2021, 37, 7, 2289–2297, Supplementary Cover Article
31. 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
30. 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
29. 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
28. 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.

2020:
27. 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
26. 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
25. 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
24. 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
23. 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.

2019：
22. 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
21. 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
20. 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
19. 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.
18. 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
17. 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.

2018：
16. 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
15. 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
14. 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
13. 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
12. A. Terzis, G. Yang, I. Zarikos, et al. A temperature-based diagnostic approach for paper-based microfluidics. Microfluidics and Nanofluidics, 2018, 22(3) : 35
11. 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
10. 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
9. 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：
8. 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
7. 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

2013-2016：
6. 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
5. 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
4. 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
3. 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
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

中文論文（部分）

29. 曹慶泰, 郭松源, 李建強(qiáng), 蔣贊, 汪彬, 耑銳, 吳靜怡, 楊光. 負(fù)過(guò)載下多孔隔板對(duì)液氧貯箱蓄液性能的影響研究. 化工學(xué)報(bào), 2025, 76(S1): 217-229.

28. 易天浩,加歡,林奕霖,等.金屬多孔陣列結(jié)構(gòu)的毛細(xì)性能實(shí)驗(yàn)[J].中國(guó)空間科學(xué)技術(shù), 2025,45(2):61-69

27. 郭松源, 周曉慶, 繆五兵, 汪彬, 耑銳, 曹慶泰, 陳成成, 楊光, 吳靜怡. 火箭上升段含多孔板液氧貯箱增壓輸運(yùn)數(shù)值研究[J]. 化工學(xué)報(bào), 2025, 76(S1): 62-74.

26.史陳芳達(dá),呂蓉蓉,李春煜,史文軍,朱子龍,劉濤,吳靜怡,楊光. 液氫海上運(yùn)輸關(guān)鍵技術(shù)發(fā)展 船電技術(shù). 2024, 01

25. 蔡愛峰,錢程,朱娟,聶曉展,程鑫,楊光,吳靜怡. 熱力耦合作用下薄壁均熱板的力學(xué)特性分析.真空與低溫,  2024 ,157-165
24. 林奕霖,王曄,陳成成,蔡愛峰,楊光,吳靜怡,雙層金屬網(wǎng)幕泡破壓力特性的實(shí)驗(yàn)研究.上海交通大學(xué)學(xué)報(bào), 2024
23. 王曄,楊光,金鑫,耑銳,任楓,汪彬,吳靜怡, 網(wǎng)幕通道式液體獲取裝置相分離特性低溫實(shí)驗(yàn)研究. 航空動(dòng)力學(xué)報(bào), 2024

22. 柳祝勛,楊光,吳靜怡. 基于矩量法的過(guò)渡區(qū)顆粒沉積核函數(shù)修正及結(jié)果驗(yàn)證[J]. 化工學(xué)報(bào),2024,75(12):4468-4476. 

21. 易天浩,邱一男,徐元元,等. 微重力下低溫流體動(dòng)態(tài)毛細(xì)爬升的數(shù)值模擬[J]. 制冷學(xué)報(bào),2023,44(4):141-149. 

20. 周曉慶,李春煜,楊光,等. 液滴撞擊不同曲率過(guò)冷波紋面結(jié)冰動(dòng)力學(xué)行為及機(jī)理研究[J]. 化工學(xué)報(bào),2023,74(z1)

19. 肖明堃,楊光,黃永華,等. 浸沒孔液氧氣泡動(dòng)力學(xué)數(shù)值研究[J]. 化工學(xué)報(bào),2023,74(z1):87-95. 

18. 楊恩博,金宇鵬,楊光,黃永華,王天祥,雷剛,吳靜怡.內(nèi)角鈍度對(duì)微重力下液體推進(jìn)劑毛細(xì)流動(dòng)特性的影響.上海交通大學(xué)學(xué)報(bào), 2023, 57, 739-746
17. 李嘉,張良俊,吳仕澤,李曉慈,蔡愛峰,楊光,吳靜怡.基于模糊PID的低溫環(huán)境試驗(yàn)系統(tǒng)控制特性研究.真空與低溫, 2023, 29, 180-187
16. 陳燕地,張婉雨,張良俊,李春煜,吳靜怡,楊光.側(cè)風(fēng)道對(duì)多孔保溫材料內(nèi)水分遷移特性的影響規(guī)律研究.真空與低溫, 2023, 29, 251-260
15. 王崢,王曄,金鑫,張浩,汪彬,耑銳,楊光,吳靜怡.網(wǎng)幕通道式液體獲取裝置的入口速度分布特性研究[J].真空與低溫,2022,28(05):556-564.
14. 王曄,張婉雨,汪彬,耑銳,任楓,蔡愛峰,楊光,吳靜怡.多孔網(wǎng)幕泡破壓力預(yù)測(cè)模型的建立及實(shí)驗(yàn)驗(yàn)證[J].化工學(xué)報(bào),2022,73(03):1102-1110.
13. 聶曉展,程鑫,王珊珊,李春煜,楊光,吳靜怡.大面積超薄蒸汽腔力學(xué)特性仿真分析[J].系統(tǒng)仿真技術(shù),2022,18(04):233-239.
12. 金宇鵬,肖明堃,邱一男,王天祥,楊光,黃永華,吳靜怡.基于磁補(bǔ)償實(shí)驗(yàn)的微重力下毛細(xì)管內(nèi)動(dòng)態(tài)流動(dòng)特性研究[J].力學(xué)學(xué)報(bào),2022,54(12):3408-3417.
11. 易天浩,楊光,黃永華,吳靜怡.基于擴(kuò)散界面法的微重力下液氫沸騰傳熱研究[J].工程熱物理學(xué)報(bào),2022,43(09):2494-2500.
10. 楊光,程鑫,王崢,王曄,張良俊,吳靜怡.微納多孔結(jié)構(gòu)中稀薄氣體流動(dòng)滲透率的解析型預(yù)測(cè)模型[J].化工學(xué)報(bào),2022,73(07):2895-2901.
9. 楊光,張良俊,張婉雨,陳燕地,杜懿岑,吳靜怡.常壓低溫環(huán)境下拋物面薄壁結(jié)構(gòu)熱平衡特性分析[J].真空與低溫,2022,28(03):333-340.
8. 楊凱中,楊光,吳靜怡.不同陽(yáng)離子分子篩中CO2吸附結(jié)構(gòu)形成與變化機(jī)理[J].真空與低溫,2021,27(06):535-542.
7. 杜懿岑,程睿杰,吳仕澤,蔡愛峰,吳靜怡,楊光.低溫非熱平衡圓柱溫度分布特性的數(shù)值分析與實(shí)驗(yàn)[J].制冷學(xué)報(bào),2020,41(06):109-116.
6. 肖明堃,黃永華,吳靜怡,楊光,耑銳.非均勻磁場(chǎng)力作用下微重力液氧氣液界面特性[J].制冷技術(shù),2020,40(06):1-11.
5. 陳亮,楊光,鄒紅菲,馬建章.從效用視角審視人工樹洞的研究與設(shè)計(jì)[J].林業(yè)科學(xué),2019,55(03):141-148.
4. 陳國(guó)珍,吳靜怡,楊光,黃一也.耦合傳熱下低溫柱體溫度均勻性的優(yōu)化分析[J].低溫與超導(dǎo),2018,46(08):6-11
3. 楊光, 吳靜怡. 三維動(dòng)態(tài)混合對(duì)流過(guò)程中的溫度均勻性分析及實(shí)驗(yàn)驗(yàn)證. 工程熱物理學(xué)報(bào), 2014, 35 : 730-734
2. 楊光, 吳靜怡. 基于小波變換和多元回歸的航天器熱循環(huán)試驗(yàn)系統(tǒng)溫度均勻性分析. 上海交通大學(xué)學(xué)報(bào), 2014, 48 :1346-1350
1. 黃一也, 楊光, 吳靜怡. 以最佳溫度均勻度和最小熵產(chǎn)為目標(biāo)的航天器熱循環(huán)試驗(yàn)系統(tǒng)運(yùn)行參數(shù)優(yōu)化. 化工學(xué)報(bào),2016, 10 : 4086-4094

會(huì)議論文（部分）
19. G. Yang, Spontaneously grown boehmite nanostructures enhancing phase change heat transfer on aluminium surfaces, μFIP 2024 Conference (Invited Talk)
18. P. Xu, A. Cai, H. Chen, H. Wang, T. Wu, J. Wu, G. Yang, Experimental study of cryogenic fluid flow in porous thermal insulation materials, ICEC29-ICMC-2024, July, 2024, Geneva, Switzerland
17. R. Xu, et al. Computations of capillary-driven cryogenic flows along interior corners with microstructure, ICEC28-ICMC 2022, Hangzhou, China
16. T. Yi, G. Yang, J. Wu, Gas breakthrough across a porous array structure wetted by cryogenic fluid, ICR2023 | 26th International Congress of Refrigeration | August 21st-25th, 2023 | Paris, France
15. C. Shi, Effect of wicking capability on the relaxation pressure of woven screens for on-orbit management of cryogenic propellants,ICEC28-ICMC 2022, Hangzhou, China
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 ICCR2013, Hangzhou, China

已授權(quán)國(guó)家發(fā)明專利：
2023：
一種低溫流體毛細(xì)輸運(yùn)性能的可視化實(shí)驗(yàn)裝置 CN202210177842.9 CN114526890B
適用于復(fù)雜過(guò)載的低溫推進(jìn)劑在軌管理裝置 CN202210317045.6 CN 114635810 B
一種雙冷源大型高低溫環(huán)境模擬試驗(yàn)系統(tǒng) CN202110630670.1 CN113368920B
一種用于大型高低溫環(huán)境模擬試驗(yàn)的機(jī)械鎖緊門封結(jié)構(gòu) CN202110561096.9 CN113351261B
一種均熱板蒸發(fā)器散熱性能的可視化測(cè)試裝置    CN202111637773.7 CN 114295399 B

2022：
一種用于熱循環(huán)試驗(yàn)設(shè)備的地面精密可調(diào)軌道結(jié)構(gòu) CN202110630821.3 CN113432899B
一種用于高低溫環(huán)境模擬試驗(yàn)系統(tǒng)的地面支撐結(jié)構(gòu) CN202110552126.X CN113443177B
2021：
一種寬溫域低溫環(huán)境試驗(yàn)裝置 CN201910635937.9 CN110346665B
一種用于研究多孔結(jié)構(gòu)中氣體流動(dòng)特性的實(shí)驗(yàn)裝置 CN201811299374.2 CN109540758B
2020以前：
一種湍流混合對(duì)流傳熱實(shí)驗(yàn)裝置 CN201610908215.2 CN106370693B
一種高低溫常壓熱循環(huán)試驗(yàn)裝置 CN201210424959.9 CN102886284B
蒸汽輸送管道沿途冷凝水回收裝置 CN201310659892.1 CN103727508B
一種大型高低溫保溫箱體 CN201310531111.0 CN103556717B
用于大型高低溫環(huán)境試驗(yàn)箱的外門啟閉結(jié)構(gòu) CN201310532975.4 CN103521277B

軟件著作權(quán)：
2023：
軟著登字第11440129號(hào) 低溫工程多相流動(dòng)與相變傳熱求解器軟件 CryoFoam-SJTU
軟著登字第11308743號(hào) 低溫流體氣液兩相界面追蹤求解器軟件 CLSVOF-SJTU
軟著登字第11305547號(hào) 薄膜型圍護(hù)結(jié)構(gòu)導(dǎo)熱系數(shù)計(jì)算軟件 MSCS
2022：
軟著登字第10311264號(hào) 高壓蒸汽腔體承力柱可視化設(shè)計(jì)軟件 SCDS