中国·3044AM永利集团(股份)有限公司-官方网站

ZHANG Bo

Researcher

School of Aeronautics and Astronautics, Room 322 bozhang@sjtu.edu.cn https://scholar.google.com/citations?hl=zh-CN&pli=1&user=3vYQaocAAAAJ

Educational Background

2008 - 2013， Beijing Institute of Technology, Doctor
2006 - 2008， Nanjing University of Science and Technology, Master
2002 - 2006， Changzhou University, Bachelor

Work Experience

2021-Present，Shanghai Jiao Tong University，Professor
2017-2020，Shanghai Jiao Tong University，Associate Professor
2015-2016，East China University of Science and Technology，Associate Professor
2012-2015，East China University of Science and Technology，Assistant Professor
2012-2014，Environmental Engineering Lab, East China University of Science and Technology，Postdoctoral Research Staff
2009-2011，McGill University and Concordia University，Visiting Scholar

Research Interests

Lean blow-out in turbine combustors
Dynamics of gaseous detonation
Explosion characteristics of combustible mixtures
Shock waves

Major Research Projects

National Natural Science Foundation of China

Representative Papers And Monographs

2025：
80) Cheng J, Zhang B*. Towards detailed combustion characteristics and linear stability analysis of premixed ammonia‒hydrogen‒air mixtures. Applications in Energy and Combustion Science,2025, 21: 100325
79) Wang CY, Zhang B*. Experimental study on the detonation propagation behavior in a thin cylindrical chamber. Aerospace Science and Technology, 2025,159: 109988
78) Chang XY, Li YF, Ge MY, Wang K, Zhang B*, Xue S*. Explosion characteristics and chemical kinetics of hydrogen-air mixture with CO2 dilution. International Journal of Hydrogen Energy, 2025, 105: 946-958
77) Cheng J, Zhang B*, Pang L, Xu JJ. Investigation on the detonation characteristics of ammonia-hydrogen-blended fuel: Experimental and theoretical analysis. International Journal of Hydrogen Energy, 2025, in press
2024：
76) Zhang B*. Enhancing detonation propulsion with jet in cross-flow: A comprehensive review. Progress in Aerospace Sciences, 2024, 147:101020
75) Yang Z, Zhang B*. Investigation on the dynamics of shock wave generated by detonation reflection. Combustion and Flame, 2024, 270:113791
74) Yang Z, Zhang B*, Ng HD. Experimental observations of gaseous cellular detonation reflection. Proceedings of the Combustion Institute, 2024, 40:105519
73) Hu J H , Zhang B*.Time/frequency domain analysis of detonation wave propagation mechanism in a linear rotating detonation combustor. Applied Thermal Engineering, 2024,255:124014
72) Hu J H , Cheng J, Zhang B*, Ng HD. The diffraction and re-initiation characteristics of gaseous detonations with an irregular cellular structure. Aerospace Science and Technology, 2024,150:109240
71) Yang Z Z, Cheng J, Zhang B*.Deflagration and detonation induced by shock wave focusing at different Mach numbers. Chinese Journal of Aeronautics, 2024, 37(2): 249-258 [SCI, IF:5.7(2023)]
70) Yang Z Z, Zhang B*, Ng HD. Detonation onset due to the energy accumulation effect of shock wave focusing. Acta Astronautica, 2024, 215:264-276 [SCI, IF:3.5 (2023)]
69) Zhang B*, Yang ZZ, Leo YD. On the dynamics of drifting flame front in a confined chamber with airflow disorder in a methane-air mixture. Fuel , 2024, 357:129761[SCI, IF:7.4 (2023)]
68) Cheng J, Zhang B*. Experimental study on the explosion characteristics of ammonia-hydrogen-air mixtures. Fuel, 2024, 363: 131046 [SCI, IF:7.4 (2023)]
2023:
67) Hu J H, Cheng J*, Zhang B*. The diffraction and re-initiation behavior of detonation wave in premixed H2–O2–Ar mixture. Physics of Fluids. 2023, 35: 095109[SCI, IF:4.6(2023)]
66) Cheng J, Zhang B*. Characteristics of flame acceleration and deflagration-to-detonation transition enhanced by SF6 jet-in-cross-flow/flame interaction, Aerospace Science and Technology, 2023,140: 108451. [SCI, IF:5.6(2023)]
65) Cheng J, Zhang B*. Analysis of explosion and laminar combustion characteristics of premixed ammonia-air/oxygen mixtures. Fuel, 2023, 351: 128860 [SCI, IF:7.4 (2023)]
64) Dai T K, Zhang B*. Effect of Air Jet Vortex Generators on the Shock Wave Boundary Layer Interaction of Transonic Wing. Aerospace, 2023, 10, 553[SCI, IF:2.6 (2023)]
63) Dai T K, Zhang B*. Simulations of Compression Ramp Shock Wave/Turbulent Boundary Layer Interaction Controlled via Steady Jets at High Reynolds Number. Aerospace, 2023, 10(10), 892[SCI, IF:2.6 (2023)]
62) Yang Z Z, Zhang B*. Numerical and experimental analysis of detonation induced by shock wave focusing. Combustion and Flame, 2023,251: 112691. [SCI, IF:4.4 (2023)]
61) Li Y C, Zhang B*. Visualization of ignition modes in methane-based mixture induced by shock wave focusing. Combustion and Flame, 2023,247: 112491. [SCI, IF: 4.4 (2023)]
60) Leo Y D, Zhang B*, Dai T K, Chang X Y. Influence of pressure and dilution gas on the explosion behavior of methane-oxygen mixtures. Fuel, 2023, 333: 126390 [SCI, IF:7.4 (2023)]
2022:
59) Zhang B*, Li Y, Liu H. Analysis of the ignition induced by shock wave focusing equipped with conical and hemispherical reflectors. Combustion and Flame, 2022,236:111763. [SCI, IF:5.767 (2022)]
58) Cheng J, Zhang B*, Yang ZZ, Liu H. Investigation of the effect of turbulence induced by double non-reactive gas jet on the deflagration-to-detonation transition. Aerospace Science and Technology, 2022,124: 107556. [SCI, IF:5.457 (2022)]
57) Cheng J, Zhang B*, Dai TK, Liu H. Effects of jet/flame interaction on deflagration-to-detonation transition by non-reactive gas jet in a methane-oxygen mixture. Aerospace Science and Technology, 2022,126: 107581. [SCI, IF:5.457 (2022)]
56) Chang X Y, Bai C H, Zhang B*. The effect of gas jets on the explosion dynamics of hydrogen-air mixtures. Process Safety and Environmental Protection , 2022, 162:384-394 [SCI, IF:7.926 (2022)]
55) Leo YD, Zhang B*. Explosion behavior of methane-air mixtures and Rayleigh-Taylor instability in the explosion process near the flammability limits. Fuel, 2022, 324: 124730 [SCI, IF:8.035 (2022)]
54) Chang X Y, Bai C H, Zhang B*, Sun B F. The effect of ignition delay time on the explosion behavior in non-uniform hydrogen-air mixtures. International Journal of Hydrogen Energy, 2022, 47:9810-9818 [SCI, IF:7.139(2022)]
2021:
53) Zhang B*, Li Y, Liu H. Ignition behavior and the onset of quasi-detonation in methane-oxygen using different end wall reflectors. Aerospace Science and Technology, 2021,116:106873. [SCI, IF:5.107 (2021)]
52) Dai T K, Zhang B*, Liu H. On the explosion characteristics for central and end-wall ignition in hydrogen-air mixtures: A comparative study. International Journal of Hydrogen Energy, 2021, 46:30861-30869 [SCI, IF: 5.816 (2021)]
51) Xiao Q P , Cheng J, Zhang B*, Zhou J, Chen W H. Schlieren visualization of the interaction of jet in crossflow and deflagrated flame in hydrogen-air mixture, Fuel, 2021, 292: 120380[SCI, IF:6.609 (2021)]
50) Cheng J, Zhang B*, Liu H, Wang FX. The precursor shock wave and flame propagation enhancement by CO2 injection in a methane-oxygen mixture. Fuel, 2021, 283:118917
49) Cheng J, Zhang B*, Ng HD , Liu H, Wang FX. Effects of inert gas jet on the transition from deflagration to detonation in a stoichiometric methane-oxygen mixture. Fuel, 2021, 285: 119237[SCI, IF:5.578 (2020)]
2020:
48) Zhang B*, Liu H, Yan BJ, Ng HD. Experimental study of detonation limits in methane-oxygen mixtures: Determining tube scale and initial pressure effects. Fuel, 2020, 259 : 116220
47) Zhang B*, Chang X Y, Bai C H. End-wall ignition of methane-air mixtures under the effects of CO2/Ar/N2 fluidic jets. Fuel, 2020, 270:117485
46) Cheng J, Zhang B*, Liu H, Wang FX. Experimental study on the effects of different fluidic jets on the acceleration of deflagration prior its transition to detonation. Aerospace Science and Technology, 2020, 106:106203. [SCI, IF:4.499 (2020)]
45) Chang X Y, Zhang B*, Ng HD, Bai C H. The effects of pre-ignition turbulence by gas jets on the explosion behavior of methane-oxygen mixtures. Fuel, 2020, 277:118190[SCI, IF:5.578 (2020)]
44) Bai C H, Chang X Y, Zhang B*. Impacts of turbulence on explosion characteristics of methane-air mixtures with different fuel concentration. Fuel, 2020, 271: 117610[SCI, IF:5.578 (2020)]
2019:
43) Zhang B*，Liu H. Theoretical prediction model and experimental investigation of detonation limits in combustible gaseous mixtures . Fuel, 2019, 258 :116132
42) Zhang B*, Liu H , Li YC. The effect of instability of detonation on the propagation modes near the limits in typical combustible mixtures. Fuel, 2019, 253:305-310.
41) Zhang B*. Detonation limits in methane-hydrogen-oxygen mixtures: Dominant effect of induction length. International Journal of Hydrogen Energy, 2019, 44: 23532-23537[SCI, IF:4.084 (2019)]
40) Yao N, Wang L Q, Bai C H, Liu N, Zhang B*. Analysis of dispersion behavior of aluminum powder in a 20 L chamber with two symmetric nozzles. Proc Safety Prog, 2019, e12097 [SCI, IF:0.885 (2019)]
39) Zhang B*，Liu H*, Yan B J. Velocity behavior downstream of perforated plates with large blockage ratio for unstable and stable detonations. Aerospace Science and Technology, 2019,86:236-243. [SCI，IF:3.050 (2019)]
38) Bai C H, Liu Nan , Zhang B*. Experimental investigation on the lower flammability limits of diethyl ether/ n-pentane/epoxypropane-air mixtures, Journal of Loss Prevention in the Process Industries, 2019, 57: 273-279[SCI，IF:1.982 (2019)]
37) Zhang B*，Liu H*, Yan B J. Effect of acoustically absorbing wall tubes on the near-limit detonation propagation behaviors in a methane-oxygen mixture. Fuel, 2019, 236:975-83. [SCI，IF:4.908 (2018)]
36) Zhang B*，Liu H*, Yan B J. Investigation on the detonation propagation limit criterion for methane-oxygen mixtures in tubes with different scales. Fuel, 2019, 239:617-22. [SCI，IF:4.908 (2018)]
2018:
35) Zhang B*，Liu H*, Wang C. Detonation propagation limits in highly argon diluted acetylene-oxygen mixtures in channels. Experimental Thermal and Fluid Science, 2018,90:125-131. [SCI，IF:2.830 (2017)]
2017:
34) Zhang B*，Liu H*. The effects of large scale perturbation-generating obstacles on the propagation of detonation filled with methane–oxygen mixture. Combustion and Flame, 2017, 182: 279-287. [SCI，IF:4.168 (2016)]
33) Zhang B*，Liu H*, Wang C. Detonation velocity behavior and scaling analysis for ethylene-nitrous oxide mixture. Applied Thermal Engineering, 2017, 127: 671-678. [SCI，IF:3.356 (2017)]
32) Zhang B*，Liu H*, Wang C*. On the detonation propagation behavior in hydrogen-oxygen mixture under the effect of spiral obstacles. International Journal of Hydrogen Energy, 2017, 42:21392-21402 [SCI，IF:3.582(2017)]
31) Zhang B*，Liu H*, Wang C. An experimental study on the detonability of gaseous hydrocarbon fuel–oxygen mixtures in narrow channels. Aerospace Science and Technology, 2017,69:193-200. [SCI，IF:2.057 (2017)]
30) Shen XB, Zhang B, Zhang XL, et al. Explosion characteristics of methane-ethane mixtures in air. Journal of Loss Prevention in the Process Industries, 2017,45:102-107. [SCI，IF:1.409(2016)]
2016:
29) Zhang B*, Wang C, Shen XB, et al. Velocity fluctuation analysis near detonation propagation limits for stoichiometric methane-hydrogen-oxygen mixture. International Journal of Hydrogen Energy.2016, 41:17750-17759. [SCI，IF:3.205(2016)]
28) Zhang B*. The influence of wall roughness on detonation limits in hydrogen-oxygen mixture. Combustion and Flame, 2016, 169:333-339. [SCI，IF:4.168 (2016)]
27) Wang C, Zhao YY, Zhang B*. Numerical simulation of flame acceleration and deflagration-to-detonation transition of ethylene in channels. Journal of Loss Prevention in the Process Industries, 2016,43:120-126. [SCI，IF:1.409(2016)]
26) Zhang B*, Ng HD. An experimental investigation of the explosion characteristics of dimethyl ether-air mixtures. Energy, 2016,107:1-8. [SCI，IF:4.292(2016)]
25) Zhang B*, Shen XB, Pang L, Gao Y. Methane-oxygen detonation characteristics near their propagation limits in ducts. Fuel. 2016,177:1-7. [SCI，IF:3.611(2016)]
24) Shen XB*, Zhang B*, Zhang XL, Wu SZ. Explosion behaviors of mixtures of methane and air with saturated water vapor. Fuel. 2016, 177:15-18. [SCI，IF:3.611 (2016)]
23) Gao Y*, Zhang B, Ng HD, Lee JHS. An experimental investigation of detonation limits in hydrogen-oxygen-argon mixtures. International Journal of Hydrogen Energy.2016, 41: 6076-6083. [SCI，IF:3.205(2016)]
22) Zhang B*, Pang L*, Shen XB*, Gao Y, Measurement and prediction of detonation cell size in binary fuel blends of methane/hydrogen mixtures. Fuel. 2016, 172:196-199. [SCI，IF:3.611 (2016)]
21) Zhang B*, Pang L*, Gao Y. Detonation limits in binary fuel blends of methane/hydrogen mixtures. Fuel. 2016,168: 27-33. [SCI，IF:3.611 (2016)]
2015:
20) Zhang B*, Shen XB*, Pang L*, Gao Y. Detonation velocity deficits of H2/O2/Ar mixture in round tube and annular channels. International Journal of Hydrogen Energy. 2015,40(43): 15078-15087. [SCI，IF:3.313(2016)]
19) Zhang B*, Shen XB*, Pang L. Effects of argon/nitrogen dilution on explosion and combustion characteristics of dimethyl ether-air mixtures. Fuel. 2015, 159: 646-652. [SCI，IF:3.52(2015)]
18) Zhang B*, Ng HD. Explosion behavior of methane–dimethyl ether/air mixtures. Fuel. 2015,157:56-63. [SCI，IF:3.52(2015)]
17) Zhang B*, Xiu GL*, Chen J, Yang SP. Detonation and deflagration characteristics of p-Xylene/gaseous hydrocarbon fuels/air mixtures. Fuel. 2015,140:73-80[SCI，IF:3.52(2015)]
2014:
16) Zhang B*, Xiu GL., Bai CH. Explosion characteristics of argon/nitrogen diluted natural gas-air mixtures. Fuel. 2014, 124:125-132 [SCI，IF:3.406(2014)]
15) Zhang B*, Bai CH. Methods to predict the critical energy of direct detonation initiation in gaseous hydrocarbon fuels-An overview. Fuel. 2014,117:294-308[SCI，IF:3.406(2014)]
14) Zhang B*, Mehrjoo N, Ng HD, Lee JHS. On the dynamic detonation parameters in acetylene-oxygen mixtures with varying amount of argon dilution. Combustion and Flame. 2014,161:1390-1397. [SCI, IF:3.708(2013)]
13) Zhang B*, Bai CH, Xiu GL, Liu QM, Gong GD. Explosion and flame characteristics of methane/air mixtures in a large-scale vessel. Process Safety Progress. 2014,33(4):362-368 [SCI, IF:0.593(2013)]
12) Mehrjoo N, Zhang B, Portaro R, Ng HD*. Lee JHS. Response of critical tube diameter phenomenon to small perturbations for gaseous detonations. Shock Waves. 2014, 24(2):219-229 [SCI, IF:0.743(2013)]
2013:
11) Zhang B, Ng, H.D*, Lee JHS. Measurement and relationship between critical tube diameter and critical energy for direct blast initiation of gaseous detonations. Journal of Loss Prevention in the Process Industries. 2013,26: 1293-1299 [SCI，IF:1.347(2013)]
10) Bai CH, Zhang B*, Xiu GL，Liu QM, Chen M. Deflagration to detonation transition and detonation structure in diethyl ether mist/aluminum dust /air mixtures. Fuel. 2013,107:400-408 [SCI，IF:3.357(2012)]
9) Yao GB, Zhang B*, Xiu GL, Bai CH, Liu PP. The critical energy of direct initiation and detonation cell size in liquid hydrocarbon fuel/air mixtures. Fuel. 2013, 113: 331-339. [SCI，IF:3.357(2012)]
8) Zhang B*, Bai CH. Critical energy of direct detonation initiation in hydrocarbon-oxygen mixtures. Safety Science. 2013, 53:153-159, [SCI，IF:1.402(2011)]
7) Bai CH, Chen J*, Zhang B，Wang, Z. Q. Effect of Explosive Sources on the Elastic Wave Field of Explosions in Soils. Defence Science Journal.2013, 63(4):376-380 [SCI，IF:0.31(2013)]
2012:
6) Zhang B*, Ng HD, Lee JHS. The critical tube diameter and critical energy for direct initiation of detonation in C2H2/N2O/Ar mixtures. Combustion and Flame, 2012,159(9): 2944-2953 [SCI，IF:3.585(2011)]
5) Zhang B, Ng HD*, Lee JHS. Measurement of effective blast energy for direct initiation of spherical gaseous detonations from high-voltage spark discharge. Shock Waves. 2012,22(1): 1-7[SCI，IF:0.951(2011)]
4) Zhang B, Ng HD*, Lee JHS. Measurement and scaling analysis of critical energy for direct initiation of detonation. Shock Waves . 2012,22(3): 275-279 [SCI，IF:0.951(2011)]
3) Eaton R, Zhang B, Bergthorson JM, Ng HD*. Measurement and chemical kinetic predictions of detonation cell size in methanol-oxygen mixtures. Shock Waves, 2012, 22(2): 173-178 [SCI，IF:0.951(2011)]
2011:
2) Zhang B, Ng HD*, Mével R, Lee JHS. Critical energy for direct initiation of spherical detonations in H2/N2O/Ar mixtures. International Journal of Hydrogen Energy, 2011, 36:5707-5716 [SCI，IF:4.054(2011)]
1) Zhang B, Kamenskihs V, Ng HD*, Lee JHS. Direct blast initiation of spherical gaseous detonation in highly argon diluted mixtures. Proceedings of the Combustion Institute, 2011, 33 (2): 2265-2271 [SCI，IF:3.633(2011)]

Honorary Information

John H.S. Lee Young Investigator Award, Institute for Dynamics of Explosions and Reactive Systems (IDERS), Leeds, UK，2015