[1] H. Li, Z. Zhang, C. Wen. Theoretical transition criteria in steady shock-incidence/detonation-reflection phenomenon. Combustion and Flame, 2026, 284: 114627.
[2] Z. Jiang, Z. Chen, L. Shi, Z. Zhang, J. Hao, C. Y. Wen. Numerical study of oblique detonation initiation assisted by local energy deposition. Aerospace Science and Technology, 2026, 168: 111278.
[3] X. Shao, Z. Zhang, L. Shi, J. Hao, C. Y. Wen. Effects of incoming boundary layer on the initiation characteristics of oblique detonation waves over a compression corner. Combustion and Flame, 2025, 282: 114539.
[4] S. Niu, P. Yang, Z. Zhang, H. Teng. Three-dimensional morphology and formation mechanism of tongue-shaped oblique detonation waves in elliptical flow channels. Combustion and Flame, 2025, 282: 114468.
[5] H. Li, Z. Zhang, K. Yao, C. Wang, C. Wen. On theoretical modeling of underdriven oblique detonation phenomenon. Physics of Fluids, 2025, 37(9): 096102.
[6] W. Zhang, R. Yang, Z. Zhang, Y. Liu, Z. Zhang, Y. Wang, H. Chen. Effects of evaporation modeling on kerosene–air oblique detonation. Journal of Propulsion and Power, 2025, 41(6): 700–715.
[7] L. Shi, Z. Zhang, E Fan, C. Y. Wen. Simulations of detonation wave reflection over cylindrical convex surfaces with a detailed reaction model. Physics of Fluids, 2025, 37(8): 081705.
[8] Z. Chen, G. Zhao, Z. Li, L. Shen, Z. Zhang, Z. Chen, C. Y. Wen. Wake flow separation control on a notchback Ahmed body using sawtooth plasma actuators. Physics of Fluids, 2025, 37(11): 111704.
[9] Z. Hu, W. Zhang, Z. Zhang. A review on the development of large-scale detonation-driven shock tunnels and the application in hypersonic flow tests. International Journal of Fluid Engineering, 2025, 2: 010601.
[10] 张子健, 温志湧. 斜爆轰发动机:斜爆轰波在受限空间中的起爆与稳定. 空气动力学学报, 2025, 43(9): 65–91.
[11] 陆亚辉, 牛淑贞, 张子健, 滕宏辉. 侧壁约束下三维燃烧室斜爆轰结构的数值研究. 空气动力学学报, 2025, 43(10): 70–84.
[12] X. Shao, Z. Zhang, L. Shi, H. Huang, C. Y. Wen. Effects of swirling inflow on the stability and combustion mode of rotating detonations. Physics of Fluids, 2024, 36: 026116.
[13] W. Zhang, Z. Zhang, X. Han, C. Yuan, Y. Liu, L. Ma, W. Ren. On the determination of the standing oblique detonation wave in an engine combustor using laser absorption spectroscopy of hydroxyl radical. Aerospace Science and Technology, 2024, 152: 109344.
[14] G. Zhao, T. Ma, Z. Chen, Z. Zhang, J. Hao, C. Y. Wen. Investigation of streamwise streak characteristics over a compression ramp at Mach 4. Physics of Fluids, 2024, 36: 104121.
[15] Y. Liu, X. Han, Z. Zhang. Study on the propulsive performance of oblique detonation engine. Energy, 2024, 292: 130519.
[16] X. Han, Y. Liu, Z. Zhang, W. Zhang, C. Yuan, G. Han, Z. Jiang. Experimental demonstration of forced initiation of kerosene oblique detonation by an on-wedge trip in an ODE model. Combustion and Flame, 2023, 258: 113102.
[17] Z. Zhang, Z. Jiang. Numerical Investigation of transverse-jet-assisted initiation of oblique detonation waves in a combustor. Aerospace, 2023, 10: 1033.
[18] Z. Zhang, Y. Liu, C. Wen. Mechanisms of the destabilized Mach reflection of inviscid oblique detonation waves before an expansion corner. Journal of Fluid Mechanics, 2022, 940: A29.
[19] Z. Zhang, C. Wen, C. Yuan, Y. Liu, G. Han, C. Wang, Z. Jiang. An experimental study of formation of stabilized oblique detonation waves in a combustor. Combustion and Flame, 2022, 237: 111868.
[20] Z. Zhang, C. Wen, W. Zhang, Y. Liu, Z. Jiang. A theoretical method for solving shock relations coupled with chemical equilibrium and its applications. Chinese Journal of Aeronautics, 2022, 35(6): 47–62.
[21] Z. Zhang, C. Wen, W. Zhang, Y. Liu., Z. Jiang. Formation of stabilized oblique detonation waves in a combustor. Combustion and Flame, 2021, 223: 423–436.
[22] Z. Jiang. Z. Zhang, Y. Liu, C. Wang, C. Luo. Criteria for hypersonic airbreathing propulsion and its experimental verification. Chinese Journal of Aeronautics, 2021, 34(3): 94–104.
[23] W. Zhang, Z. Zhang, Z. Jiang, X. Han, Y. Liu, C. Wang. Numerical investigation of free oblique detonation wave induced by non-intrusive energy deposition. AIP Advances, 2021, 11: 125119.
[24] Z. J. Zhang, C. Y. Wen, Y. F. Liu, D. L. Zhang, Z. L. Jiang. Effects of different particle size distributions on aluminum particle–air detonation. AIAA Journal, 2020, 58(7): 3115–3128.
[25] Z. Zhang, K. Ma, W. Zhang, X. Han, Y. Liu, Z. Jiang. Numerical investigation of a Mach 9 oblique detonation engine with fuel pre-injection. Aerospace Science and Technology, 105, 106054, 2020.
[26] H. Teng, S. Liu, Z. Zhang. Unsteady combustion mode with a super-high frequency induced by a curved shock. Physics of Fluids, 2020, 32: 116101.
[27] K. Wang, Z. Zhang, P. Yang, H. Teng. Numerical study on reflection of an oblique detonation wave on an outward turning wall. Physics of Fluids, 2020, 32: 046101.
[28] K. Ma, Z. Zhang, Y. Liu, Z. Jiang. Aerodynamic principles of shock-induced combustion ramjet engines. Aerospace Science and Technology, 2020, 103: 105901.
[29] Z. Zhang, C. Wen, Y. Liu, D. Zhang, Z. Jiang. Application of CE/SE method to gas-particle two-phase detonations under a Eulerian-Lagrangian framework. Journal of Computational Physics, 2019, 394: 18–40.
[30] Y. Fang, Z. Zhang, Z. Hu. Effects of boundary layer on wedge-induced oblique detonation structures in hydrogen-air mixtures. International Journal of Hydrogen Energy, 2019, 44: 23429–23435.
[31] Y. Fang, Z. Zhang, Z. Hu, X. Deng. Initiation of oblique detonation waves induced by a blunt wedge in stoichiometric hydrogen-air mixtures. Aerospace Science and Technology, 2019, 92: 676–684.
[32] J. Peng, Z. Zhang, Z. Hu, Z. Jiang. A theoretical and computational study of the vibration excitation on the transition criteria of shock wave reflections. Aerospace Science and Technology, 2019, 89: 299–306.
