教育背景
博士 201507 清华大学 核研院
硕士 201907 清华大学 计算机系
学士 201007 四川大学 物理学院
工作履历
202206-至今 清华大学核研院107室 副教授
202104-202205 清华大学核研院107室 助理教授
201710-202102 美国圣路易斯华盛顿大学 研究科学家
201509-201709 清华大学热能系 博士后
研究领域
先进核能系统与复杂多相流,包括复杂多相流理论与实验技术、核能制氢理论与应用、人工智能技术与先进核能系统设计等
学术成果
[1] Wu, C., Wu, B., Zhang, H.* and Yin, H., 2025. Study on the performance of membrane reactor using steam methane reforming for hydrogen production heated by HTGR. Nuclear Engineering and Technology, p.103744.
[2] Peng, L., Zhang, S., Zhang, H., Zhao, J., Jiang, K., Zheng, W., Du, B., Yin, H., He, X. and Ma, T., 2025. Study on permeability from 3D images of nuclear grade graphite IG-110 by the multidimensional capillary bundle model, lattice Boltzmann method and experiment. Annals of Nuclear Energy, 213, p.111144.
[3] Wu, C.Y., Zhang, H.*, Wang, Z.Y., Yin, H., 2025. Comprehensive study on parameter sensitivity analysis of steam reformer tube for hydrogen production using HTGR. Annals of Nuclear Energy, 213, 111159.
[4] Peng, L., Zhang, S., Zhang, H., et al., 2025. Study on permeability from 3D images of nuclear grade graphite IG-110 by the multidimensional capillary bundle model, lattice Boltzmann method and experiment. Annals of Nuclear Energy, 213, 111144.
[5] Zheng, W., Li, H., Du, B., Zhang, H., Yin, H., He, X. and Ma, T., 2024. Corrosion behaviors of Inconel 617 and Incoloy 800H in impure helium with different CO contents at high temperatures. Progress in Nuclear Energy, 172, p.105188.
[6] Liu, R., Li, H., Zhang, H.*, Yin, H., Ma, T., 2024. Study on tritium permeation behavior in primary and second circuits of the hydrogen production system by methane steam reforming using HTGR. Nuclear Engineering and Design, 421, p.113101.
[7] Du, B., Zhang, H., Zheng, W., Li, H., He, X., Ma, T., Yin, H., 2024. Carburization and tensile behavior of Alloy 617 in impure helium containing a part-per-million level of CH4 at 950 ◦C. Corrosion Science, 227, p.111660.
[8] Zheng, W., Zhang, H., Du, B., Li, H., Yin, H., He, X. and Ma, T., 2023. Effect of impurity ratios on the high-temperature corrosion of Inconel 617 and Incoloy 800H in impure helium. Annals of Nuclear Energy, 189, p.109836.
[9] Li, H., Zhang, H., Zheng, W., Du, B., Yin, H., He, X., Ma, T. and Yang, X., 2023. Study on oxidation kinetics of three kinds of candidate superalloys for VHTR under air ingress accident. Annals of Nuclear Energy, 189, p.109844.
[10] Zhang, Y., Zhang, H., Liu, Q., Zhou, J., 2023. Application of one-dimensional heat and mass transfer model of helium heated reformer coupled with HTR-10, Annals of Nuclear Energy, 189, p.109769.
[11] Liu, Q., Ma, Y. and Zhang, H.*, 2023. Numerical investigation on droplet collision phenomena in moisture separators using population balance model under Lagrangian framework. Annals of Nuclear Energy, 186, p.109722.
[12] Zheng, W., Zhang, H., Du, B., Li, H., Yin, H., He, X. and Ma, T., 2022. High-Temperature Corrosion Behavior of Incoloy 800H Alloy in the Impure Helium Environment. Science and Technology of Nuclear Installations, 2022.
[13] Zhang, Y., Zhang, H., Liu, Q., Zhou, J. 2022. Numerical simulation on flow and reaction characteristics for catalytic region in helium-heated steam reformer coupled with HTR-10. Progress in Nuclear Energy, 154, p. 104435.
[14] Ma, Y., Zhang, H. and Liu, Q., 2022. Experimental study on spreading and splashing behavior of continuous droplets impacting on heated wall. International Journal of Heat and Mass Transfer, 196, p. 123219.
[15] Hu, G., Zhang, H., Liu, Q., 2022. Assessment on population balance model and wall boiling model for subcooled boiling flow of steam generator of nuclear power plant. Annals of Nuclear Energy, 173, p. 109128.
[16] Hu, G., Zhang, H. and Liu, Q., 2022. Design optimization on characteristics of packed-bed thermal energy storage system coupled with high temperature gas-cooled reactor pebble-bed module. Energy Conversion and Management, 257, p.115434.
[17] Ma, Y., Hu, G., Zhang, H. and Liu, Q., 2022. Comparison of breakup and coalescence kernels in population balance model for modeling isothermal gas-liquid flow. Nuclear Engineering and Design, 388, p.111616.
[18] Okonkwo, O., Zhang, H., Li, K., Liu, Q. and Biswas, P., 2022. Thermodynamic analysis of hydrocarbon reforming. Journal of CO2 Utilization, 60, p.101998.
