2017-2021 瑞典隆德大学 流体力学专业 博士
2014-2017 华中科技大学 动力机械及工程专业 硕士
2010-2014 华中科技大学 热能与动力工程专业 学士

2024 至今 上海交通大学 hga010网页登录 助理教授、博士生导师
2023-2024 英国伯明翰大学 机械工程学院 玛丽居里学者
2021-2023 瑞典隆德大学 能源科学学院 博士后

（一）方法研究
1. 高效、高精度反应流模拟方法；
2. 机器学习与燃烧模拟的结合；
3. 湍流反应流的数据同化。

（二）应用研究
1. 燃气轮机、内燃机等低碳清洁燃烧技术；
2. 喷雾燃烧中的点火、火焰稳定与污染物生成；
3. 闪急沸腾及其在动力装置和芯片制造等领域的应用。

1. 欧盟地平线欧洲“玛丽·斯沃德斯卡-居里行动”（MSCA-PF）项目，主持；
2. 欧盟地平线2020“社会挑战-智慧、绿色、综合交通”（H2020-MG）项目，参与；
3. 瑞典瓦伦宝基金会（KAW）高科学潜力研究项目，参与；
4. 北欧能源研究署北欧五国海上运输和能源研究合作基金项目，参与；
5. 瑞典国家自然科学基金项目，参与。

期刊论文：

2024年
[38] Xu S*, Qiu Y, Xu L, et al. Phase change and combustion of iron particles in premixed CH4/O2/N2 flames. Combustion and Flame, 2024, 259: 113171.
[37] Zhang Y, Zhang Q, Cheng C, Xu S*, et al. Effects of droplet evaporation on negative temperature coefficient phenomenon and a prediction model for two-stage auto-ignition. Combustion and Flame, 2024, 262: 113376.
[36] Qiu Y*, Feng S, Wu Z, Xu S, Ruan C, Bai X S, Nilsson E, Aldén M, Li Z. Detailed numerical simulation and experiments of a steadily burning micron-sized aluminum droplet in hot steam-dominated flows. Proceeding of Combustion Institute, 2024, 40: 105717.
[35] Zhou Y, Xu S, Xu L, Bai X S*. FGM modeling of ammonia/n-heptane combustion under RCCI engine conditions. Proceeding of Combustion Institute, 2024, 40: 105601.
[34] Wu Z, Ruan C*, Stiti M, Xu S, Bai X S, Berrocal E, Aldén M, Li Z. Spatiotemporally resolved surface temperature measurement of aluminum ignition and combustion in steam and oxygenated environments. Combustion and Flame, 2024, 264: 113446.
[33] Feng S, Qiu Y, Xu S, et al. Modeling of micron-sized aluminum particle combustion in hot gas flow. Fuel, 2024, 369: 131718.
[32] Chen J, Peng F, Tian B, Kong C, Zheng Y*, Xu S, Liu Y, Cai W. Simultaneous temperature and particle size measurement of burning iron particles using a single color camera. Measurement, 2024, 241: 115679.
[31] Peng F, Kong C, Liu H, Mi X, Xu S, Liu Y, Cai W. Ignition and combustion of a single iron particle with impurities in hot post-flame gas flow. Combustion and Flame, 2024, 265:113509.

2023年
[30] Hadadpour A, Xu S*, Zhang Y, Bai X S, Jangi M. An extended FGM model with transported PDF for LES of spray combustion. Proceeding of Combustion Institute, 2023, 39: 4889-4898.
[29] Zhong S, Xu S, Zhang F*, Peng Z, Chen L, Bai X S. Cool flame propagation in high pressure spray flames. Proceeding of Combustion Institute, 2023, 39: 2513-2522.
[28] Xu L*, Xu S, Bai X S*, Repo J A, Hautala S, Hyvönen J. Performance and emission characteristics of an ammonia/diesel dual-fuel marine engine. Renewable and Sustainable Energy Reviews, 2023: 185: 113631.
[27] Xu L*, Xu S, Lu X, Jia M, Bai X S*. Large eddy simulation of spray and combustion characteristics of biodiesel and biodiesel/butanol blend fuels in internal combustion engines. Applications in Energy and Combustion Science, 2023, 185: 100197.
[26] Ong J, Zhang Y, Xu S, Walther J, Bai X S, Pang K M. Large eddy simulation of n-dodecane spray flame: Effects of injection pressure on spray combustion characteristics at low ambient temperature. Proceeding of Combustion Institute, 2023, 39: 2631-2642.
[25] Yang M, Shenghui Zhong S, Xu S, Xu L, Ottosson P, Fatehi H, Bai X-S*. CFD simulation of biomass combustion in an industrial circulating fluidized bed furnace. Combustion Science and Technology, 2023, 195: 3310-3340.
[24] Zhang M, Ong J*, Pang K M, Xu S, Zhang Y, Nemati A, Bai X S Walther J H. Large eddy simulation of combustion recession: Effects of ambient temperature and injection pressure. Fuel, 2023, 351: 128831.
[23] Zhang Y, L Xu*, Zhu Y, Xu S, Bai X S. Numerical study on liquid ammonia direct injection spray characteristics under engine-relevant conditions. Applied Energy, 2023, 334: 120680.

2022年
[22] Xu S, Zhong S, Zhang F, Bai X S*. On the element mass conservation in Eulerian stochastic field modelling of turbulent combustion. Combustion and Flame, 2022, 239: 111577.
[21] Hadadpour A*, Xu S, Pang K M, Bai X S, et al. Effects of pre-injection on ignition, combustion and emissions of spray under engine-like conditions. Combustion and Flame, 2022, 241: 112082.
[20] Zhong S, Xu L, Xu S, et al. Assessment of grid/filter size dependence in large eddy simulation of high-pressure spray flames. Fuel, 2022, 329: 125316.
[19] Guo L, Zhai M*, Xu S, Shen Q, Dong P, Bai X S, Flame characteristics of methane/air with hydrogen addition in the micro adjustable-spaced combustor. International Journal of Hydrogen Energy, 2022, 47: 19319-19337.

2021年
[18] Xu S*, Pang K M, Li Y, Hadadpour A, et al. LES/TPDF investigation of the effects of ambient methanol concentration on pilot fuel ignition characteristics and reaction front structures. Fuel, 2021, 287: 119502.
[17] Xu S*, Zhong S, Hadadpour A, Zhang Y, et al. Large-eddy simulation of the injection timing effects on the dual-fuel spray flame. Fuel, 2021, 310: 122445.
[16] Huang J, Li S, Sanned D, Xu L, Xu S, Cai W, Qian Y*, Berrocal E, Aldén M, Li Z.S. A detailed study on the micro-explosion of burning iron particles in hot oxidizing environments. Combustion and Flame, 2021, 238: 111755.
[15] Ong J*, Walther J H, Xu S, et al. Effects of ambient pressure and nozzle diameter on ignition characteristics in diesel spray combustion. Fuel, 2021, 290: 119887.
[14] Zhong S, Xu S, Bai X S*, et al. Large eddy simulation of n-heptane/syngas pilot ignition spray combustion: ignition process, liftoff evolution and pollutant emissions. Energy, 2021, 233: 121080.
[13] Zhong S, Xu S, Bai X S*, et al. Combustion characteristics of n-heptane spray combustion in a low temperature reform gas/air environment. Fuel, 2021, 293: 120377.

2020年
[12] Xu S*, Zhong S, Pang K M, et al. Effects of ambient methanol on pollutants formation in dual-fuel spray combustion at varying ambient temperatures: A large-eddy simulation. Applied Energy, 2020, 279: 115774.
[11] Zhang Y, Xu S, Zhong S, et al. Large eddy simulation of spray combustion using flamelet generated manifolds combined with artificial neural networks. Energy and AI, 2020, 2: 100021.

2019年及以前
[10] Xu S, Huang S, Huang R*, et al. Estimation of turbulence characteristics from PIV in a high-pressure fan-stirred constant volume combustion chamber. Applied Thermal Engineering, 2017, 110: 346-355.
[9] Pucilowski M, Li R, Xu S, et al. Comparison of kinetic mechanisms for numerical simulation of methanol combustion in DICI heavy-duty engine. No. 2019-01-0208. SAE Technical Paper, 2019.
[8] Huang S, Zhang Y, Huang R*, Xu S, Ma Y, Wang Z. Quantitative characterization of crack and cell's morphological evolution in premixed expanding spherical flames. Energy, 2019, 171: 161-169.
[7] Zhang Y, Huang R*, Huang Y, Huang S, Ma Y, Xu S, Zhou P. Effect of ambient temperature on the puffing characteristics of single butanol-hexadecane droplet. Energy, 2018, 145: 430-441.
[6] Zhang Y, Huang Y, Huang R*, Huang S, Ma Y, Xu S, Wang Z. A new puffing model for a droplet of butanol-hexadecane blends. Applied Thermal Engineering, 2018, 133: 633-644.
[5] Zhang Y, Huang R*, Xu S, Huang Y, Huang S, Ma Y. The effect of different n-butanol-fatty acid methyl esters (FAME) blends on puffing characteristics. Fuel, 2017, 208: 30-40.
[4] Ma Y, Huang S, Huang R*, Zhang Y, Xu S. Ignition and combustion characteristics of n-pentanol-diesel blends in a constant volume chamber. Applied Energy, 2017, 185: 519-530.
[3] Zhang Y, Huang R*, Wang Z, Xu S, Huang S, Ma Y. Experimental study on puffing characteristics of biodiesel-butanol droplet. Fuel, 2017, 191: 454-462.
[2] Ma Y, Huang R*, Huang S, Zhang Y, Xu S. Experimental investigation on the effect of n-pentanol blending on spray, ignition and combustion characteristics of waste cooking oil biodiesel. Energy Conversion and Management, 2017, 148: 440-455.
[1] Ma Y, Huang R*, Huang S, Zhang Y, Xu S. Spray and evaporation characteristics of n-pentanol-diesel blends in a constant volume chamber. Energy Conversion and Management, 2016, 130: 240-251.

会议报告：
[5] Xu S, Treacy M, Bai X S*. On the combustion modes of ammonia/n-heptane dual-fuel spray combustion: 2D DNS. The 1st Symposium on Ammonia Energy, UK, 2022.
[4] Xu S, Zhang Y, Zhong S, Bai X S*. Automatic generation of the reaction progress variable: a novel approach based on the artificial neural network. The 2nd International Conference on Energy and AI, UK, 2021.
[3] Xu S, Zhong S, Hadadpour A, et al. Effects of the injection timing on the dual-fuel spray flame: A large-eddy simulation. The 2nd world congress on internal combustion engines, China, 2021.
[2] Xu S, Bai X S*, Li Y, et al. Modeling of ammonia solution spray and mixing in selective catalytic reduction (SCR) system. The 11th International Conference on Applied Energy, Sweden, 2019.
[1] Xu S, Bai X S*, Li Y, Xu L. CFD study of selective catalytic reduction (SCR) ammonia solution spray in exhaust pipe of diesel engines. The 37th International Symposium on Combustion, Ireland, 2018.

邀请报告：
- 许世杰. 液氨直喷与双燃料燃烧的高保真数值模拟. 交通能源与智能动力大会 (TEIP), 中国天津, 2023.
- Xu S. Numerical simulation of metal particle combustion. The 1st Workshop on Metal-enabled Cycle of Renewable Energy (MECRE), The Netherlands, 2022.

国际燃烧学会（The Combustion Institute）会员；
担任 Combustion and Flame，Proceedings of the Combustion Institute，Applications in Energy and Combustion Science，Combustion Science and Technology，Fuel，International Journal of Hydrogen Energy，Energy and AI，SAE，实验流体力学等期刊/会议论文审稿人；
担任波兰国家科学中心（National Science Center, Poland）项目审稿人。

2022年，欧盟，玛丽·居里学者（Marie Skłodowska-Curie Actions Postdoctoral Fellowships）
2021年，能源与人工智能国际会议，最佳报告奖
2020年，瑞典隆德大学，哈康·汉森基金会奖
2016年，教育部 (中国)，国家奖学金（硕士）
2014年，湖北省教育厅，优秀学士学位论文