何国强 , 宋泽林 , 魏祥庚 , 冯奕铭 , 张洪宁 , 崔猛 , 牛云飞 , 刘雄峰 , 赵昊阳 . 常温绿色液体推进剂发展现状与趋势[J]. 航空学报, 0 : 1 -0 . DOI: 10.7527/S1000-6893.2026.33446

[1]侯晓.组合循环发动机技术研究进展[J].航空学报, 2023, 44(21):35-47
[2]侯晓, 李永, 武志文, 等.我国空间推进技术领域发展思考与建议[J].中国工程科学, 2024, 26(03):217-225
[3]贺芳, 方涛, 李亚裕, 等.新型绿色液体推进剂研究进展[J].火炸药学报, 2006, 29(04):54-57
[4]Cavender D P, Marshall W M, Maynard A P.2018 NASA green propulsion technology development roadmap[R]. 2018.
[5]Scharlemann C.Green advanced space propulsion-A project status[C]//47th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit. 2011: 5630.
[6]K.Anflo, S. Moore, P. King. Expanding the ADN-based monopropellant thruster family[C]//Annual AIAA/USU conference on small satellites. 2009: 176-183.
[7]Zou J J, Zhang X, Pan L.High-energy-density fuels for advanced propulsion: Design and synthesis[M]. John Wiley & Sons, 2020.
[8]Pan Y, Zhang H, Zhang C, et al.Supercritical pyrolysis and coking of JP-10 in regenerative cooling channels[J].Energy & Fuels, 2020, 34(2):1627-1638
[9]刘天池, 范育新, 赵世龙, 等.高温条件下-航空煤油的结焦特性[J].航空动力学报, 2020, 35(02):348-357
[10]李艳玲, 冀克俭, 赵晓刚, 等.高张力笼状化合物四环庚烷的分子结构表征及热裂解[J].含能材料, 2017, 25(08):622-626
[11]Sutton G P.History of liquid-propellant rocket engines in Russia,formerly the Soviet Union[J].Journal of Propulsion and Power, 2003, 19(6):1008-1037
[12]张星, 姚传奇, 蒋榕培, 等.高能合成煤油-性能研究[J].推进技术, 2021, 42(07):1671-1680
[13]孙海云, 蒋榕培, 李春红, 等.高能合成煤油-理化性能及应用分析[J].载人航天, 2016, 22(05):619-623
[14] 雷小洋.典型高能量密度燃料裂解与燃烧机理研究[D]. 成都:四川大学, 2023: 2.
[15]邹吉军, 郭成, 张香文, 等.航天推进用高密度液体碳氢燃料:合成与应用[J].推进技术, 2014, 35(10):1419-1425
[16]王贞, 卫豪, 贺芳, 等.高密度合成烃类燃料研究进展[J]. 导弹与航天运载技术, 2011, (03):41-46.
[17]杜宗罡, 朱成财, 吴金, 等.火箭煤油降阻技术研究[J].火箭推进, 2017, 43(06):32-37
[18]罗玉宏, 游岳, 蒋榕培, 等.添加减阻剂的火箭煤油流阻与传热特性研究[J].火箭推进, 2018, 44(05):66-70
[19]冯弦, 于忻立, 杜宗罡, 等.降阻煤油石墨烯纳米流体制备及传热强化研究[J].当代化工, 2024, 53(11):2678-2682
[20]魏奇, 苏鑫鑫.超燃冲压发动机用液体正烷烃燃料的燃烧特性[J].飞航导弹, 2010, (11):76-81.
[21]WANG H, ZHANG B, GONG S, et al.Experimental and modeling studies of quadricyclane and 2-ethylnorbornane pyrolysis from atmospheric to high pressure[J]. Combustion and Flame, 2021, 226: 163-181.
[22]李攀, 赵宇, 吴兴国, 等.生物乙醇制备航空煤油的研究进展[J].工程科学学报, 2025, 47(03):514-525
[23]仲富, 戴继民.无水乙醇制备新进展[J].山东化工, 2020, 49(19):68-
[24]Butt M A.The Effect of Ambient Humidity on Evaporation of Ethanol-Water Solutions[D]. University of Toronto (Canada), 2024.
[25]孙海云, 方涛, 贺芳.高能低毒离子液体推进剂研究进展[C]// 中国化学会第五届全国化学推进剂学术会议论文集.北京航天试验技术研究所, 2011:168-172.
[26]SUN C G, TANG S K, ZHANG X W.Role of cation structures for energetic performance of hypergolic ionic liquids[J].Energy & Fuels, 2017, 31(9):10055-10059
[27]Clarke C J, Tu W C, Levers O, et al.Green and sustainable solvents in chemical processes[J].Chemical reviews, 2018, 118(2):747-800
[28]Gao H, Joo Y H, Twamley B, et al.Hypergolic ionic liquids with the 2,2-dialkyltriazanium cation[J].Angewandte Chemie International Edition, 2009, 48(15):2792-2795
[29]焦念明, 张延强.离子液体自燃推进剂的研究进展[J].工程研究, 2022, 14(6):483-498
[30]Schneider S, Hawkins T, Rosander M, et al.Ionic liquids as hypergolic fuels[J].Energy&Fuels, 2008, 22(4):2871-2872
[31]费腾, 徐冉, 赵鹏宇, 等.离子型短点火延迟自燃液体推进剂研究进展[J].火箭推进, 2024, 50(05):33-43
[32]符立言, 焦冰晶, 王棒棒, 等.硼氢类自燃离子液体的研究进展[J].含能材料, 2022, 30(11):1155-1166
[33]Kim K S, Bhosale V K, Kwon S.Synergistic effect of a hybrid additive for hydrogen peroxide-based low toxicity hypergolic propellants[J]. Combustion and Flame, 2021, 231: 111450.
[34]Lauck F, Balkenhohl J, Negri M, et al.Green bipropellant development–A study on the hypergolicity of imidazole thiocyanate ionic liquids with hydrogen peroxide in an automated drop test setup[J]. Combustion and Flame, 2021, 226: 87-97.
[35]李兴业, 王琦, 高永涛, 等.绿色含硼离子液体推进剂的研究进展[J].化学推进剂与高分子材料, 2016, 14(4):1-7
[36]Guseinov S L, Fedorov S, Kosykh V, et al.Hydrogen peroxide decomposition catalysts used in rocket engines[J].Russian Journal of Applied Chemistry, 2020, 93(4):467-487
[37]Surmacz P, Gut Z.The experimental investigation of a 98% hydrogen peroxide monopropellant thruster comprising the Metal-Foam-Supported manganese oxide catalyst[J].Aerospace, 2023, 10(3):215-
[38]Butler K.AR2-3 engine refurbishment and gas generator testing[C]//35th Joint Propulsion Conference and Exhibit. 1999: 2738.
[39]WEI Y Q, WANG B Y, WEI X G, et al.Analysis of the dynamic characteristics of the forced start-up procedure of H2O2/kerosene gas generator cycle rocket engine system[J].Aerospace Science and Technology, 2025, 161.
[40]Kim P, Majamaki A, Papesh C, et al.Design and Development Testing of the TR108-a 30Klbf-Thrust-Class Hydrogen Peroxide/Hydrocarbon Pump-Fed Engine[C]//41st AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit. 2005: 3566.
[41]Guerrero J, Hamilton B, Burton R, et al.Upper stage flight experiment (USFE) integral structure development effort[J].Composite structures, 2004, 66(1-4):327-337
[42]宋培荣, 孙得川.含铝过氧化氢凝胶推进剂的点火过程[J].火炸药学报, 2024, 47(12):1155-1162
[43]Kang S, Oh S.Endurance characteristic affected by pressure drop across catalyst bed of hydrogen peroxide monopropellant thruster[J].Journal of the Brazilian Society of Mechanical Sciences and Engineering, 2023, 45(2):113-
[44]魏祥庚, 孟彤, 刘红军, 等.一种基于第三流体的过氧化氢/煤油火箭发动机推力室: 202010893328.6[P]. 2021-12-24.
[45]张宝炯.过氧化氢推进技术的复苏[J]. 火箭推进, 2002 28(1): 7-13.
[46]Türker L.Hypergolic systems based on hydrogen peroxide oxidizer[J].Earthline Journal of Chemical Sciences, 2023, 10(1):1-42
[47]Mota F A S, Fei L, Tang C, et al.Hypergolic ignition behaviors of green propellants with hydrogen peroxide: The TMEDA/DMEA system[J]. Fuel, 2023, 336: 127086.
[48]Anderson W S, Heister S D, Kan B, et al.Experimental study of a hypergolically ignited liquid bipropellant rotating detonation rocket engine[J].Journal of Propulsion and Power, 2020, 36(6):851-861
[49]Hueter U, McClinton C, Cook S.NASA' s advanced space transportation hypersonic program[C]//11th AIAA/AAAF International Conference Space Planes and Hypersonics Systems and Technologies Conference. 2002 (AIAA Paper 2002-5175).
[50]Walker J F, Kamhawi H, Krivanek T M, et al.Status of the RBCC direct-connect mixer combustor experiment[C]//Combustion, Airbreathing Propulsion, Propulsion Systems Hazards, and Modelling and Simulation Subcommittes Joint Meeting. 2002 (NAS 1.15: 211555).
[51]程永喜, 温婧, 刘旭.美国高浓度过氧化氢与金属材料相容性研究进展[J].化学推进剂与高分子材料, 2018, 16(5):10-19
[52]McCormick J C.Hydrogen Peroxide Rocket Manual[M]. FMC Corporation, 1965.
[53]Ventura M.Long term storability of hydrogen peroxide[C]//41st AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit. 2005: 4551.
[54]Homung S D, Davis D D, Baker D, et al.Hydrogen Peroxide-Material Compatibility Studied by Microcalorimetry[R]. 2003.
[55]Engelke R, Sheffield S A, Davis L L.Experimental and predicted detonation parameters for liquid-phase H2O2H2O mixtures[J].The Journal of Physical Chemistry A, 2000, 104(29):6894-6898
[56]李辛涛.铝钪合金与高浓度过氧化氢的相容性[J]. 航天制造技术, 2007 (6): 15-19.
[57]孙庆国, 石泽华, 李兆坚.高浓度过氧化氢贮运安全技术研究[J].石油和化工设备, 2019, 22(09):102-104
[58]李厚金, 李金珊, 陈六平.过氧化氢：小分子，大作用[J].大学化学, 2021, 36(06):41-48
[59]胡长诚.国外过氧化氢稳定剂研究概况综述[J].化学推进剂与高分子材料, 2002, (04):1-3.
[60]朱希增, 朱顺兵, 刘新华.有机磷酸稳定剂对双氧水绝热分解特性的影响[J].化工进展, 2014, 33(12):3197-3202
[61]Акионерное общество " Государственный Ордена Трудового Красного Знамени научно-исследовательский институт химии и технологии элементоорганических соединений" (АО " ГНИИХТЭОС" ).[ru]СПОСОБ ДОПОЛНИТЕЛЬНОЙ СТАБИЛИЗАЦИИ ВЫСОКОКОНЦЕНТРИРОВАННОГО ПЕРОКСИДА ВОДОРОДА ДЛЯ ЕГО ХРАНЕНИЯ И ТРАНСПОРТИРОВКИ В ЕМКОСТЯХ ИЗ НЕРЖАВЕЮЩЕЙ СТАЛИ: RU2014108507/05[P]. 2015-12-20.
[62]Gibbon D, Baker A, Coxhill I, et al.The development of a family of resistojet thruster propulsion systems for small spacecraft[J]. 2003.
[63]Zakirov V, Richardson G, Sweeting M.Surrey research update on N2O catalytic decomposition for space applications[C]//37th Joint Propulsion Conference and Exhibit. 2001: 3922.
[64]Smith N, Moser M, Kopicz, Jr C, et al.Nitrous oxide/propane rocket test results[C]//36th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit. 2000: 3222.
[65]CAI G B, SUN W, FANG J, et al.Design and performance characterization of a sub-Newton N2O monopropellant thruster[J].Aerospace Science and Technology, 2012, 23(1):439-451
[66]龚亮.一氧化二氮单组元发动机系统方案设计及仿真研究[D].长沙:国防科学技术大学, 2013.
[67]王正凯.基于再生冷却的自增压方案研究[D].长沙:国防科学技术大学, 2015.
[68]Taylor R.Safety and performance advantages of nitrous oxide fuel blends (NOFBX) propellants for manned and unmanned spaceflight applications[J]. A Safer Space for Safer World, 2012, 699: 67.
[69]逄凯, 李新艳, 李效斯, 等.推进剂技术的发展概况[J].兵器装备工程学报, 2023, 44(10):147-158
[70]Mungas G, Vozoff M, Rishikof B.NOFBX: A new non-toxic, Green propulsion technology with high performance and low cost[C]//Proceedings of the 63 International Astronautical Congress, Naples, Italy. 2012: 1-5.
[71]Werling L K, H?rger T, Manassis K, et al.Nitrous oxide fuels blends: research on premixed monopropellants at the german aerospace center (DLR) since 2014[C]//AIAA Propulsion and Energy 2020 Forum. 2020: 3807.
[72]李森, 白梅杉, 姚天亮.硝酸羟胺推进技术发展现状与趋势[J].中国航天, 2024, (01):63-69.
[73]彭清涛, 黄小光, 胡文祥, 等.硝酸羟胺水溶液的制备及其含量分析[J].上海航天, 2003, 20(2):52-55
[74]Wei C, Rogers W J, Mannan M S.Thermal decomposition hazard evaluation of hydroxylamine nitrate[J].Journal of hazardous materials, 2006, 130(1-2):163-168
[75]程红波, 王拯, 陶博文, 等.硝酸羟胺热分解特性及其稳定化技术研究[J].化学推进剂与高分子材料, 2018, 16(04):80-85
[76]汪洪涛, 周集义.硝酸羟胺·制备及其稳定剂综述[J].化学推进剂与高分子材料, 2007, 5(02):18-23
[77]任晓光, 李明慧, 王爱琴, 等.室温条件下硝酸羟胺的催化分解[J].催化学报, 2007, 28(01):1-2
[78]王新强, 邓康清, 李洪旭, 等.基绿色推进剂点火技术研究进展[J].火箭推进, 2017, 43(02):72-76
[79]Tanaka N, Matsuo T, Furukawa K, et al.The “greening” of spacecraft reaction control systems[J].Mitsubishi Heavy Industries Technical Review, 2011, 48(4):44-50
[80]Tummala A R, Dutta A.An overview of cube-satellite propulsion technologies and trends[J].Aerospace, 2017, 4(4):58-
[81]鲍立荣, 汪辉, 陈永义, 等.硝酸羟胺基绿色推进剂研究进展[J].含能材料, 2020, 28(12):1200-1210
[82]黄振芝, 苗思薇, 刘俊.美国发布2018年新版《绿色推进技术发展路线图》[J].军民两用技术与产品, 2020, (07):32-37.
[83]Nagamachi M Y, Oliveira J I S, Kawamoto A M, et al.ADN-The new oxidizer around the corner for an environmentally friendly smokeless propellant[J].Journal of Aerospace Technology and Management, 2009, 1(2):153-160
[84]鲍世国, 马天举, 田国庆, 等.新型绿色单组元液体推进剂发展现状与趋势[J].火箭推进, 2024, 50(05):1-22
[85]马智勇, 朱少敏, 丛伟民, 等.氨水与金属离子对基绿色推进剂稳定性影响[J].推进技术, 2021, 42(11):2610-2616
[86]李雷.二硝酰胺铵（ADN）基液体推进剂电点火及燃烧特性研究[D].北京:北京交通大学, 2023.
[87]侯阳阳.ADN基液体推进剂的微波点火特性及应用研究[D].北京:北京交通大学, 2024.
[88]Wingborg N, Elds?ter C, Skifs H.Formulation and characterization of ADN-based liquid monopropellants[C]//Proceedings of the 2nd International Conference on Green Propellants for Space Propulsion (ESA SP-557). 7-8 June 2004, Chia Laguna (Cagliari), Sardinia, Italy. Editor: A. Wilson. Published on CDROM., id. 16.1. 2004, 557.
[89]周劲松, 马英华, 于海成, 等.高氯酸羟胺的制备及应用[J].化学推进剂与高分子材料, 2002, (02):1-5+15.
[90]田苗, 杨艳, 魏刚, 等.铝合金耐高氯酸羟胺腐蚀防护方法研究[J].热加工工艺, 2016, 45(24):113-115
[91]付小龙, 蔚红建, 张崇民, 等.推进剂的能量性能研究[J].兵器装备工程学报, 2020, 41(11):23-28
[92]冯昱嘉, 孙振华, 王坤, 等.含硼凝胶冲压发动机技术研究进展[J].航空学报, 2025, 46(14):6-30
[93]王雨桐, 潘伦, 张香文, 等.氨硼烷水解制氢研究进展[J].化工学报, 2021, 72(01):180-191
[94]Pfeil M A, Groven L J, Lucht R P, et al.Effects of ammonia borane on the combustion of an ethanol droplet at atmospheric pressure[J].Combustion and flame, 2013, 160(10):2194-2203
[95]Lee J, Weismiller M, Connell T, et al.Ammonia borane based-propellants[C]//44th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit. 2008: 5037.
[96]Staubitz A, Robertson A P M, Manners I.Ammonia-borane and related compounds as dihydrogen sources[J].Chemical reviews, 2010, 110(7):4079-4124
[97]刘木子, 史柯柯, 赵强, 等.固体储氢材料的研究进展[J].化工进展, 2023, 42(09):4746-4769
[98]邹爱华, 林路贺, 周浪, 等.氨硼烷合成、表征及金属纳米催化剂水解制氢研究进展[J].燃料化学学报中英文, 2023, 51(07):909-920
[99]黄飞.高能燃料组分的热安全性能研究[D].太原:中北大学, 2015.
[100]FENG Y F, WANG H Z, CHEN X D, et al.Simple synthesis of Cu2O–CoO nanoplates with enhanced catalytic activity for hydrogen production from ammonia borane hydrolysis[J].International Journal of Hydrogen Energy, 2020, 45(35):17164-17173
[101]李猛, 赵凤起, 徐司雨, 等.含金属氢化物的复合推进剂能量特性[J].固体火箭技术, 2014, 37(01):86-90
[102]Herrmann M, F?rter-Barth U, Weyrauch H, et al.Microstructure of Aluminum Hydride and Stabilization Concepts[C]//Fraunhofer Institute for Chemical Technology (ICT International Annual Conference) 2022. 2022.
[103]Foster H H, Fletcher E A, Straight D M.Aluminum Borohydride-Hydrocarbon Mixtures as a Source of Ignition for a Turbojet Combustor[R]. 1955.
[104]伍婷婷, 刘建忠, 陈冰虹, 等.基于纳米铝颗粒改性合成稳定的-基纳米流体燃料[J].工程热物理学报, 2021, 42(07):1887-1894
[105]鄂秀天凤, 彭浩, 邹吉军, 等.含有纳米铝颗粒的高密度悬浮燃料研究[J].推进技术, 2016, 37(05):974-978
[106]CHEN A Q, GUAN X D, LI X M, et al.Preparation and Characterization of Metalized JP-10 Gel Propellants with Excellent Thixotropic Performance[J].Propellants, Explosives, Pyrotechnics, 2017, 42(9):1007-1013
[107]曹锦文, 潘伦, 张香文, 等.含纳米铝颗粒的-凝胶燃料理化及流变性能[J].含能材料, 2020, 28(05):382-390
[108]E X T F, ZHI X M, ZHANG Y M, et al.Jet fuel containing ligand-protecting energetic nanoparticles: a case study of boron in JP-10[J]. Chemical Engineering Science, 2015, 129: 9-13.
[109]李春天, 王志文, 鲍立荣, 等.凝胶推进技术研究进展[J].固体火箭技术, 2024, 47(01):4-14
[110]Dressler G, Bauer J.TRW pintle engine heritage and performance characteristics[C]// 36th AiAA/ASME/SAE/ASEE joint propulsion conference and exhibit. 2000: 3871.
[111]史喆.高能燃料三氢化铝的稳定性调控及燃烧性能研究[D].哈尔滨:哈尔滨工业大学, 2023.
[112]Clements K A, Baier M J, Ramachandran P V, et al.Experimental study of factors affecting hypergolic ignition of ammonia borane[J].Journal of Propulsion and Power, 2021, 37(2):202-210
[113]刘毅, 鄂秀天凤, 李智欣, 等.高能量密度液体燃料的火箭发动机燃烧性能研究[J].推进技术, 2019, 40(05):1169-1176
[114]JIN Y S, XU X, WANG X, et al.Propulsive and combustion behavior of hydrocarbon fuels containing boron nanoparticles in a liquid rocket combustor[J].Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 2022, 236(12):2580-2591
[115]金磊磊, 刘建忠, 李和平, 等.型三氢化铝点火燃烧特性研究进展[J].兵器装备工程学报, 2018, 39(12):171-177
[116]张娜, 陈红, 马骁, 等.高密度固态储氢材料技术研究进展[J].载人航天, 2019, 25(01):116-121
[117]E X T F, PAN L, WANG F, et al.Al-Nanoparticle-Containing Nanofluid Fuel: Synthesis,Stability,Properties,and Propulsion Performance[J].Industrial & Engineering Chemistry Research, 2016, 55(10):2738-2745
[118]JIN Y S, XU X, YANG Q C, et al.Combustion Behavior of HydrocarbonBoron Gel-Fueled Scramjet[J].AIAA Journal, 2022, 60(6):3834-3843
[119]王宁飞.固体推进剂燃烧不稳定性研究[J].火炸药学报, 1995, 18,(1):47-50
[120]Pfeil M A, Son S F, Anderson W E.Influence of ammonia borane on the stability of a liquid rocket combustor[J].Journal of Propulsion and Power, 2014, 30(2):290-298