2009.09-2015.06     上海交通大學(xué)，動(dòng)力工程及工程熱物理，碩博連讀 (導(dǎo)師： 鄭平 院士)
2013.07-2013.10     瑞士洛桑聯(lián)邦理工學(xué)院（EPFL），    (導(dǎo)師： Prof. J.R. Thome)            
2005.09-2009.06     華中科技大學(xué)，熱能與動(dòng)力工程，學(xué)士

2026.02 至今              長聘副教授，上海交通大學(xué)

2020.01-2026.01       長聘教軌副教授，上海交通大學(xué)
2017.11-2019.11       博士后，麻省理工學(xué)院（MIT）機(jī)械工程系 （導(dǎo)師: Evelyn N. Wang院士）
2015.05-2017.11       博士后，上海交通大學(xué)

微/納尺度汽液相變傳熱；

電子芯片熱管理；

潤濕與界面動(dòng)力學(xué)；
電催化制氫


歡迎感興趣的同學(xué)聯(lián)系 長期招收相關(guān)領(lǐng)域方向博士、碩士研究生。

主持項(xiàng)目：

國家自然科學(xué)基金面上項(xiàng)目：2024-2027，超薄復(fù)合吸液芯內(nèi)介電流體的納-微尺度蒸發(fā)傳熱特性和機(jī)理研究
上海市自然科學(xué)基金：2023-2025，氣泡動(dòng)力學(xué)對(duì)微納結(jié)構(gòu)電極電解水析氫能質(zhì)傳遞的影響機(jī)理
上海交通大學(xué)深藍(lán)計(jì)劃：2023-2024；
國家科技重大專項(xiàng)子課題：RPV下封頭外壁面沸騰換熱機(jī)理；
國家自然科學(xué)基金青年基金
上海市浦江人才計(jì)劃項(xiàng)目(A類) 

等......


主參項(xiàng)目：
未來能源計(jì)劃聯(lián)合科研基金-先進(jìn)固態(tài)熱管堆關(guān)鍵分析軟件研發(fā)及試驗(yàn)研究，2022-2024；
國家自然科學(xué)基金重點(diǎn)國際合作項(xiàng)目（2015-2019）：納米流體高效吸收太陽能產(chǎn)生蒸汽的機(jī)理研究；
國家自然科學(xué)基金重點(diǎn)項(xiàng)目（2011-2014）：電場強(qiáng)化汽/液/固三相接觸區(qū)域相變傳熱的研究，主要貢獻(xiàn)人

期刊論文

2026

1] Jia Wei, Zhongxiao Liu, Shuai Gong*, Ping Cheng, Effects of contact angle hysteresis on nucleate boiling bubble dynamics and heat transfer, International Journal of Heat and Mass Transfer 256 (2026) 128122.

2025

1] Zhiheng Hu, Shuai Gong*, Chaoyang Zhang*, Ping Cheng, A Unified Approach for Truncated and Extended Adsorbed Liquid Films in Evaporating Menisci, Applied Physics Letters 126, 231604 (2025). 

2] Junyang Li, Shuai Gong*, Chaoyang Zhang, Ping Cheng, Three-Dimensional Pore-Scale Simulations of Thin-film Evaporation on Micro-pillar Wicks, Physics of Fluids 37, 063336 (2025).

3] Zhongxiao Liu, Jia Wei, Shuai Gong*, Ping Cheng, High Fidelity Simulations of Single Bubble Nucleate Boiling Heat Transfer Considering Microscale Effects,

International Journal of Heat and Mass Transfer 2025, 239, 126584.

4] S.Y. Guan, Z.H. Zhang, S. Gong, R. Wu, X.K. Gu, C.Y. Zhao*, Molecular insights into the mechanism of nucleation in nanopores: Heat transfer characteristics and two-phase behaviors, International Journal of Heat and Mass Transfer 241 (2025), 126775.

5] Naiqian Zhang, Shuai Gong*, Zhiheng Hu, Chaoyang Zhang, Ping Cheng, Lattice Boltzmann Modeling of Interfacial Mass Transfer: Mass Accommodation Coefficient in Liquid-Vapor Phase Change, International Communications in Heat and Mass Transfer 169 (2025) 109769.

6] Yawen Ding, Shasha Ma, Shuai Gong*, Evaporation Heat Transfer Characteristics of Fourth-Generation Refrigerants in Nano/Microchannels, Langmuir  2025, 41, 28704?28717.

7] Yizhou Han, Shuai Gong*, Zhiheng Hu, Chaoyang Zhang, and Ping Cheng, What Causes Anomalously High Bubble Nucleation Superheats in Nucleate Boiling Simulations by the Lattice Boltzmann Method? Physics of Fluids 37, 112114 (2025).

2024  
1] Ming Jiao, Ping Cheng*, Mingguang Zheng, Li Zhang, Shuai Gong*, CHF Enhancements of Flame-Sprayed Porous Coatings on the Outer Surface of Reactor Pressure Vessel Bottom Head, International Journal of Heat and Mass Transfer 232 (2024) 125930.
2] Shuai Gong*, Zhiheng Hu, Ping Cheng*, A Mesoscopic Approach for Nanoscale Evaporation Heat Transfer Characteristics, International Journal of Heat and Mass Transfer 231 (2024) 125856.
3] Panpan Zhao, Shuai Gong*, Chaoyang Zhang, Siliang Chen, Ping Cheng, Roles of Wettability and Wickability on Enhanced Hydrogen Evolution Reactions, ACS Applied Materials & Interfaces 2024, 16, 27898–27907.
4] Junyang Li, Chaoyang Zhang, Ping Cheng, Shuai Gong*, Three-Dimensional Pore-Scale Simulations of Dynamic Wicking Processes on Micro-Structured Wicks, Physics of Fluids 36, 042112 (2024).
5] Zhiheng Hu, Shuai Gong*. Correction to “Mesoscopic Model for Disjoining Pressure Effects in Nanoscale Thin Liquid Films and Evaporating Extended Meniscuses”, Langmuir 2024, 40, 5, 2781.
6] Zhiyuan Ma , Chaoyang Zhang , Shuai Gong , Chun Yang , P. Cheng*, Lattice Boltzmann simulation of water droplet impact and freezing on inclined supercooled surfaces with different roughnesses and wettabilities, International Journal of Heat and Mass Transfer 233 (2024) 126051.
7] Shikang Yin, Zhenhua Jiang, Shuai Gong, Bingyao Lin*, Deping Dong, Simulation and Experimental Study of Two-Phase Gas–Liquid Behavior in Two-Dimensional Porous Medium Based on Lattice Boltzmann Method, Journal of Thermal Science and Engineering Applications 2025, 17(2): 021006.


2023
1] Shuai Gong , Zhiheng Hu, Lining Dong, and Ping Cheng*, Temperature- and Curvature-dependent surface tensions and Tolman lengths for real fluids: a mesoscopic investigation, Physics of Fluids, 35, 073315 (2023).
2] Wenhan Zheng, Fangjun Hong*, and Shuai Gong. Improved multi-relaxation time thermal pseudo-potential lattice Boltzmann method with multi-block grid and complete unit conversion for liquid–vapor phase transition. Physics of Fluids 35, 053337, 2023.
3] Zhiheng Hu, Shuai Gong*. Mesoscopic Model for Disjoining Pressure Effects in Nanoscale Thin Liquid Films and Evaporating Extended Meniscuses, Langmuir 2023, 39, 13359–13370.
4]  Panpan Zhao, Chaoyang Zhang, Shuai Gong*, Size Ranges of Effective Nucleation Cavities on Gas-evolving Surfaces, Langmuir 2023, 39, 45, 16101–16110.


2022
1] Shuai Gong*, Fangjun Hong, Qing Guo, Lenan Zhang, Ping Cheng*, Mesoscopic Approach for Nanoscale Liquid-Vapor Interfacial Statics and Dynamics, International Journal of Heat and Mass Transfer, 194, 2022, 123104.
2] Junyang Li#, Shuai Gong#, *, Lenan Zhang, Ping Cheng*, Xiaojing Ma, Fangjun Hong, Wetting States and Departure Diameters of Bubbles on Micro-/Nanostructured Surfaces, Langmuir 2022, 38, 10, 3180–3188.
3] Panpan Zhao, Zhiheng Hu, Ping Cheng, Rongzong Huang, and Shuai Gong*，Coalescence-Induced Bubble Departure: Effects of Dynamic Contact Angles，Langmuir 2022, 38, 34, 10558–10567.
4] Ryuichi Iwata, Lenan Zhang, Zhengmao Lu, Shuai Gong, Jianyi Du, Evelyn N Wang. How Coalescing Bubbles Depart from a Wall, Langmuir, 2022, 38, 14, 4371–4377.
5] Lenan Zhang#, Shuai Gong#, Zhengmao Lu, Ping Cheng*, Evelyn N. Wang*, "Boiling crisis due to bubble interactions," International Journal of Heat and Mass Transfer, 182, 2022, 121904.
6] Zhaolong Wang, Yingying Li, Shuai Gong, Wenhao Li, Huigao Duan, Ping Cheng, Yongping Chen, and Zhichao Dong, Three-Dimensional Open Water Microchannel Transpiration Mimetics, ACS Applied Materials & Interfaces, 2022, 14, 26, 30435–30442.
7] Wenhan Zheng, Jian Li, Fangjun Hong*, Shuai Gong, Ping Cheng. Mesoscale Simulations on the Ultrahigh Heat Flux Evaporation of R143a within Ultrathin Nanoporous Membrane Using a Modified Dimensionless Lattice Boltzmann Method, International Journal of Heat and Mass Transfer 192, 2022, 122939.

2021
1] Youngsup Song, Shuai Gong, Geoffrey Vaartstra, and Evelyn N. Wang*. Microtube surfaces for simultaneous enhancement of efficiency and critical heat flux during pool boiling, ACS Applied Materials & Interfaces, 2021, 13, 10, 12629-12635.
2] Ryuichi Iwata, Lenan Zhang, Kyle Wilke, Shuai Gong, Mingfu He, Betar M. Gallant and Evelyn N. Wang, Bubble growth and departure modes on wettable/non-wettable porous foams in alkaline water splitting, Joule, 5(4), 2021, 887-900.
3] Lenan Zhang, Zhenyuan Xu, Lin Zhao, Bikram Bhatia, Yang Zhong, Shuai Gong and Evelyn N. Wang, Passive, high-efficiency thermally-localized solar desalination, Energy & Environmental Science, 14(4),  2021, 1771-1793.

2020
1] Shuai Gong#, Lenan Zhang#, Ping Cheng*, Evelyn N. Wang*, Understanding triggering mechanisms for critical heat flux in pool boiling based on direct numerical simulations, International Journal of Heat and Mass Transfer, 163, 120546, 2020.
2] Lenan Zhang#, Shuai Gong#, Zhengmao Lu, Ping Cheng, Evelyn N. Wang*, A unified relationship between bubble departure frequency and diameter during saturated nucleate pool boiling, International Journal of Heat and Mass Transfer, 165, Part A, 2021, 120640.
3] Lenan Zhang, Ryuichi Iwata, Lin Zhao, Shuai Gong, Zhengmao Lu, Zhenyuan Xu, Yang Zhong, Jinlong Zhu, Samuel Cruz, Kyle L. Wilke, Ping Cheng*, Evelyn N. Wang*, Nucleation Site Distribution Probed by Phase-Enhanced Environmental Scanning Electron Microscopy, Cell Reports Physical Science, 2020, 100262.    

2019年以前
1.      Shuai Gong and Ping Cheng*, Direct numerical simulations of pool boiling curves including heater's thermal responses and the effect of vapor phase's thermal conductivity, International Communications in Heat and Mass Transfer 87 (2017) 61-71.
2. Shuai Gong and Ping Cheng*, Two-dimensional mesoscale simulations of saturated pool boiling from rough surfaces. Part II: Bubble interactions above multi-cavities, International Journal of Heat and Mass Transfer 100 (2016) 938-948.
3. Shuai Gong, Ping Cheng* and Xiaojun Quan, Two-dimensional mesoscale simulations of saturated pool boiling from rough surfaces. Part I: Bubble nucleation in a single cavity at low superheats, International Journal of Heat and Mass Transfer 100 (2016) 927-937.
4. Shuai Gong and Ping Cheng*, Lattice Boltzmann simulations for surface wettability effects in saturated pool boiling heat transfer, International Journal of Heat and Mass Transfer 85 (2015) 635-646.
5. Shuai Gong and Ping Cheng*, Numerical simulation of pool boiling heat transfer on smooth surfaces with mixed wettability by lattice Boltzmann method, International Journal of Heat and Mass Transfer 80 (2015) 206-216.
6. Shuai Gong and Ping Cheng*, Numerical investigation of saturated flow boiling in microchannels by the lattice Boltzmann method, Numerical Heat Transfer, Part A 65 (2014) 644-661.
7. Shuai Gong and Ping Cheng*, Lattice Boltzmann simulation of periodic bubble nucleation, growth and departure from a heated surface in pool boiling, International Journal of Heat and Mass Transfer 64 (2013) 122-132.
8. Shuai Gong and Ping Cheng*, A lattice Boltzmann method for simulation of liquid-vapor phase-change heat transfer, International Journal of Heat and Mass Transfer 55 (2012) 4923-4927.
9. Shuai Gong and Ping Cheng*, Numerical investigation of droplet motion and coalescence by an improved lattice Boltzmann model for phase transitions and multiphase flows, Computers & Fluids 53 (2012) 93-104.
10. Shuai Gong, Ping Cheng* and Xiaojun Quan, Lattice Boltzmann simulation of droplet formation in microchannels under an electric field, International Journal of Heat and Mass Transfer 53 (2010) 5863-5870.
11. Lining Dong, Shuai Gong* and Ping Cheng, Direct numerical simulations of film boiling heat transfer by a phase-change lattice Boltzmann method, International Communications in Heat and Mass Transfer 91 (2018) 109-116.
12. Ping Cheng*, Chaoyang Zhang and Shuai Gong. Lattice Boltzmann simulations of macro/microscale effects on saturated pool boiling curves for heated horizontal surfaces, Journal of Heat Transfer 139.11 (2017): 110801.
13. Xiaojing Ma, Ping Cheng*, Shuai Gong and Xiaojun Quan, Mesoscale simulations of saturated pool boiling heat transfer under microgravity conditions, International Journal of Heat and Mass Transfer 114 (2017) 453-457.

14. 龔帥, 鄭平*. 液滴在非均勻潤濕表面上的動(dòng)力行為. 上海交通大學(xué)學(xué)報(bào), 2014, 48(2): 239-244.
15. 龔帥, 郭照立*. 橫向振蕩圓柱繞流的格子 Boltzmann方法模擬，力學(xué)學(xué)報(bào)，43 (5) 2011: 809-818.
16. 龔帥, 郭照立*. 流向振蕩圓柱繞流的格子 Boltzmann方法模擬，力學(xué)學(xué)報(bào)，43(1) 2011:10-17.


專著
1. P. Cheng, X. Quan, S. Gong, X. Liu and L. Yang, Chapter Four-Recent analytical and numerical studies on phase-change heat transfer, Advances in Heat Transfer 46, 2014, 187-248, Elsevier.
2. P. Cheng, S. Gong, C. Zhang, Chapter Four-Lattice Boltzmann Simulations of Saturated Pool Boiling from Smooth and Rough Horizontal Surfaces, Encyclopaedia of Two-Phase Heat Transfer and Flows IV, 2018, 209-237, World Scientific Publishing Company.