（1）激波与爆轰物理；

（2）高超爆轰推进技术；

（3）爆炸与冲击动力学。

（9）2023.1-2026.12，国家自然科学基金面上项目（12272234）：激波聚焦作用下气液掺混燃料爆轰诱导机制与优化控制方法，负责人（在研）；

（8）2022.9-2025.8，上海市2022年度“科技创新行动计划”政府间国际科技合作项目，负责人（在研）；

（7）2022.4-2025.3，上海市自然科学基金面上项目，负责人（在研）；

（6）2022.1-2024.12，国防科技173计划技术领域基金项目，负责人（在研）；

（5）2018.1-2021.12，国家自然科学基金面上项目（11772199）：气相多元混合燃料爆轰极限动力学特性研究，负责人（已结题）；

（4）2019.1-2020.12，工信部安全专项：低温推进剂应急设施安全距离研究，交大负责人（已结题）；

（3）2018.1-2020.12，国家自然科学基金“面向发动机的湍流燃烧基础研究重大研究计划”培育项目（91741114）：面向爆轰发动机的射流模式对激励爆轰起爆的湍流机制研究，负责人（已结题）；

（2）2015.1-2017.12，国家自然科学基金青年项目（11402092）：不稳定性对气相爆轰波起爆与传播影响机理的研究，负责人（已结题）；

（1）2014.7-2015.12，中国博士后基金特别资助：气相混合燃料爆炸和爆轰的特征规律研究，负责人（已结题）。

共计出版专著1部，发表论文83篇，其中SCI论文71篇，ESI高被引论文7篇。SCI被引3100余次，h-index:36 (统计至2024.3)

 

2024：

（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:5.767 (2022)]

（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:5.767 (2022)]

（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:8.035 (2022)]

 

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（ESI高被引）

（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（ESI高被引）

（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 （ESI高被引）

（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（ESI高被引）

（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. （ESI高被引）

（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)]

 

中文期刊论文：

（12）专著：张博，白春华. 气相爆轰动力学[M]，科学出版社，31.2万字，2012

（11）韩文虎，张博，王成. 气相爆轰波起爆与传播机理研究进展. 爆炸与冲击，2021，41（12): 121402 (EI)

（10）颜秉健, 张博*，等. 气相爆轰波近失效状态的传播模式. 爆炸与冲击，2018，38（6):1435-1440 (EI)

（9）张博*，白春华.气相爆轰动力学特征研究进展.中国科学(物理学 力学 天文学). 2014, 44(7): 665-681.

（8）高慧会，张博*，等. 二甲醚/空气/氩气混合物的爆炸特性. 爆炸与冲击，2015, 35(5): 753-757 (EI).

（7）张博*，白春华. 高电压点火有效能量的测量及相关问题. 爆炸与冲击，2013, 33(1): 85-90， (EI).

（6）张博*，白春华. H₂-O₂/Air直接起爆形成爆轰临界能量的预测模型. 高压物理学报，2013, 27(5):719-724.

（5）张博*，白春华. C₂H₂-O₂-Ar混合气体爆轰特征参数研究.高压物理学报，2013, 27(2): 287-291.

（4）张博*，白春华. C₂H₂-O₂-Ar和C₂H₂-N₂O-Ar直接起爆形成爆轰的临界能量.爆炸与冲击, 2012, 32(6):592-598 (EI).

（3）张博*，John H.S. Lee，白春华. 高浓度氩气稀释对C₂H₂-2.5O₂气体直接起爆临界起爆能量影响的实验研究. 高压物理学报，2012, 26(1):55-62 (EI).

（2）张博*，John H.S. Lee，白春华.C₂H₄-O₂混合气体直接起爆的临界能量. 爆炸与冲击，2012 , 32(2):113-120， (EI).

（1）张博*，白春华，John H.S. Lee.C₂H₂-2.5O₂-Ar混合气体临界管径和爆轰胞格及临界起爆能量的实验研究.北京理工大学学报. 2012, 32(3):226-230 (EI).

 

发明专利：

（7）张博，程俊，刘洪. 一种基于交错射流的湍流强化火焰加速系统及方法，授权号：ZL202110853879.4

（6）张博，李元昌，刘洪. 一种激波聚焦点火及相应点火特性测量装置及方法, 授权号：ZL202110699623.2

（5）张博，刘洪，代廷楷，程俊，李元昌.一种基于高速射流的爆轰激励系统及方法, 授权号：ZL201910497759.8

（4）张博，李元昌，程俊，代廷楷，刘洪. 一种爆燃波传播特性的测试装置及方法，授权号：ZL202010057724.5

（3）张博，沈晓波，于文强，陈婷，陈潇，李嘉晨，谢禄霖.一种监测爆轰波速度变化的系统及方法.2014.10. 授权号：ZL 201410669242.X

（2）张博，白春华.可燃气体爆轰临界管径的测试系统和方法， 2013.9，授权号：ZL20121 0052665.8

（1）张博，白春华.直接起爆形成爆轰的临界能量测试方法， 2013.7，授权号：ZL20121 0058653.6

 

教学工作

课程名称：燃烧学

授课对象：本科生

学时数：48

学分：3