Advanced search
Publication Cover
Combustion Science and Technology Volume 179, 2007 - Issue 10
Submit an article Journal homepage
876
Views
39
CrossRef citations to date
0
Altmetric
Original Articles

HYPERGOLIC REACTION MECHANISMS OF CATALYTICALLY PROMOTED FUELS WITH ROCKET GRADE HYDROGEN PEROXIDE

TIMOTHÉE L. POURPOINT Purdue University, West Lafayette, INCorrespondence[email protected]
&
WILLIAM E. ANDERSON Purdue University, West Lafayette, IN
Pages 2107-2133 | Received 24 Jul 2006, Accepted 22 Jan 2007, Published online: 10 Oct 2007

Citations (39)

Keep up to date with the latest research on this topic with citation updates for this article.

Subscribe to citation updates

Read on this site (3)

David A. Castaneda, Samuel Hassid, Joseph K. Lefkowitz & Benveniste Natan. (2022) Modeling Hypergolic Ignition Based on Thermal Diffusion for Spherical and Cylindrical Geometries. Combustion Science and Technology 0:0, pages 1-18.
Read now
Ariel T. Black, Michael P. Drolet & Timothée L. Pourpoint. (2019) Early Liquid and Gas Phase Hypergolic Reactions between Monomethylhydrazine and Nitrogen Tetroxide or Red Fuming Nitric Acid. Combustion Science and Technology 191:11, pages 1990-2005.
Read now
ShahramG. Pakdehi, S. Ajdari, A. Hashemi & Mohammad Hossein Keshavarz. (2015) Performance Evaluation of Liquid Fuel 2-Dimethyl Amino Ethyl Azide (DMAZ) with Liquid Oxidizers. Journal of Energetic Materials 33:1, pages 17-23.
Read now

Articles from other publishers (36)

Fábio A. S. Mota, Lihan Fei, Mingyang Liu, Jiawei Jiang & Chenglong Tang. (2024) Novel Hypergolic Green Fuels with Hydrogen Peroxide for Propulsion Systems. Journal of Propulsion and Power 40:2, pages 207-219.
Crossref
Roni Goldin, Syamantak Nath, Joseph K. Lefkowitz & Benveniste Natan. (2024) HYPERGOLIC IGNITION OF A KEROSENE-BASED GEL FUEL WITH HYDROGEN PEROXIDE IN ROCKET MOTORS. International Journal of Energetic Materials and Chemical Propulsion 23:2, pages 67-78.
Crossref
Syamantak Nath, Lovely Mallick & Joseph K. Lefkowitz. (2023) Hypergolic ignition response to oxidizer droplet properties. Combustion and Flame 258, pages 113061.
Crossref
Chungman Kim, Hongjae Kang, Kyounghwan Lee & Jongkwang Lee. (2023) Research and Review of Impinging Jet Test for Low-toxicity Hypergolic Propellant. Journal of the Korean Society of Propulsion Engineers 27:3, pages 78-87.
Crossref
Fábio A.S. Mota, Lihan Fei, Chenglong Tang, Zuohua Huang & Fernando S. Costa. (2023) Hypergolic ignition behaviors of green propellants with hydrogen peroxide: The TMEDA/DMEA system. Fuel 336, pages 127086.
Crossref
Lemi Türker. (2023) Hypergolic Systems based on Hydrogen Peroxide Oxidizer. Earthline Journal of Chemical Sciences, pages 1-42.
Crossref
Natan Petrutik, Ilia Kaminker, Eli Flaxer, Daniel Shem-Tov, Tsabar Giladi, Yossi Bar-Bechor, Jagadish Das & Michael Gozin. (2023) Janus-type hypergolic fuels for hybrid systems using hydrogen peroxide and hydroxylammonium nitrate-based oxidizers. Chemical Engineering Journal 454, pages 140170.
Crossref
Syamantak Nath, Iker Laso, Lovely Mallick, Zeev Sobe, Shay Koffler, Batia Blumer-Ganon, Elena Borzin, Natan Libis & Joseph K. Lefkowitz. (2023) Comprehensive ignition characterization of a non-toxic hypergolic hybrid rocket propellant. Proceedings of the Combustion Institute 39:3, pages 3361-3370.
Crossref
Lemi Türker. (2022) Interaction of DMAZ and TEMED - A DFT Treatise. Earthline Journal of Chemical Sciences, pages 163-176.
Crossref
Seonghyeon Park, Kyounghwan Lee, Hongjae Kang, Youngchul Park & Jongkwang Lee. (2022) Effects of oxidizing additives on the physical properties and ignition performance of hydrogen peroxide-based hypergolic propellants. Acta Astronautica 200, pages 48-55.
Crossref
Kyounghwan Lee, Seonghyeon Park, Hongjae Kang & Jongkwang Lee. (2022) Non-ignition Evaluation Method for Hypergolic Propellant Using Microreactor. Journal of the Korean Society of Propulsion Engineers 26:2, pages 20-27.
Crossref
Kyu-Seop Kim, Sangwoo Jung & Sejin Kwon. (2022) Optical visualization of hypergolic burning spray structure using blue light spectrum. Acta Astronautica 193, pages 230-236.
Crossref
Amanda Farias de Ferreira Miranda, Glauco Favilla Bauerfeldt & Leonardo Baptista. (2022) Numerical simulation of the gas-phase thermal decomposition and the detonation of H2O2/H2O mixtures. Reaction Kinetics, Mechanisms and Catalysis 135:2, pages 619-637.
Crossref
Keigo Hatai & Taiichi Nagata. (2022) Quantitative Clarification of Stable Ignition Region for HKP110 Green Hypergolic Bipropellant. Aerospace 9:3, pages 129.
Crossref
Syamantak Nath, Iker Laso & Joseph Lefkowitz. (2022) Parametric Ignition Study of a Green Hypergolic Hybrid Rocket Fuel. Parametric Ignition Study of a Green Hypergolic Hybrid Rocket Fuel.
Vikas Khandu Bhosale, Jinseong Gwak, Kyu-Seop Kim, David G. Churchill, Yunho Lee & Sejin Kwon. (2021) Rapid ignition of “green” bipropellants enlisting hypergolic copper (II) promoter-in-fuel. Fuel 297, pages 120734.
Crossref
Łukasz Jan Kapusta, Łukasz Boruc & Jan Kindracki. (2021) Pressure and temperature effect on hypergolic ignition delay of triglyme-based fuel with hydrogen peroxide. Fuel 287, pages 119370.
Crossref
Seonghyeon Park, Hongjae Kang, Youngchul Park & Jongkwang Lee. (2020) A Review of the Technical Development on Green Hypergolic Propellant. Journal of the Korean Society of Propulsion Engineers 24:4, pages 79-88.
Crossref
Kangcai Wang, Tianlin Liu, Yunhe Jin, Shi Huang, Natan Petrutik, Daniel Shem-Tov, Qi-Long Yan, Michael Gozin & Qinghua Zhang. (2020) “Tandem-action” ferrocenyl iodocuprates promoting low temperature hypergolic ignitions of “green” EIL–H 2 O 2 bipropellants . Journal of Materials Chemistry A 8:29, pages 14661-14670.
Crossref
Anna E. Thomas, Steven D. Chambreau, Neil D. Redeker, Alan A. Esparza, Evgeny Shafirovich, Tatjana Ribbeck, Jan A. P. Sprenger, Maik Finze & Ghanshyam L. Vaghjiani. (2020) Thermal Decomposition and Hypergolic Reaction of a Dicyanoborohydride Ionic Liquid. The Journal of Physical Chemistry A 124:5, pages 864-874.
Crossref
Jerin John, Purushothaman Nandagopalan, Seung Wook Baek & Sung June Cho. (2020) Hypergolic ignition delay studies of solidified ethanol fuel with hydrogen peroxide for hybrid rockets. Combustion and Flame 212, pages 205-215.
Crossref
Kyu-Seop Kim, Yehyun Kim, Sangwoo Jung, Junyeong Jeong & Sejin Kwon. (2019) Research Studies of Impingement Characteristics for Hypergolic Propellant. Journal of the Korean Society of Propulsion Engineers 23:5, pages 90-100.
Crossref
Anna Thomas, Steven D. Chambreau & Ghanshyam L. Vaghjiani. (2018) Ignition Delay Reduction with Sodium Addition to Imidazolium-Based Dicyanamide Ionic Liquid. The Journal of Physical Chemistry A 123:1, pages 10-14.
Crossref
Sh. L. Guseinov, S. G. Fedorov, V. A. Kosykh & P. A. Storozhenko. (2018) Hypergolic propellants based on hydrogen peroxide and organic compounds: historical aspect and current state. Russian Chemical Bulletin 67:11, pages 1943-1954.
Crossref
Yu-Ta Chen & Jing-Yuan Zhou. (2018) The Auto-Ignition of Kerosene-Based Synthetic Fuel/Hydrogen Peroxide Propellants and Its Injector Design. The Auto-Ignition of Kerosene-Based Synthetic Fuel/Hydrogen Peroxide Propellants and Its Injector Design.
Hongjae Kang, Eunkwang Lee & Sejin Kwon. (2017) Suppression of Hard Start for Nontoxic Hypergolic Thruster Using H2O2 Oxidizer. Journal of Propulsion and Power 33:5, pages 1111-1117.
Crossref
Hongjae Kang & Sejin Kwon. (2017) Green hypergolic combination: Diethylenetriamine-based fuel and hydrogen peroxide. Acta Astronautica 137, pages 25-30.
Crossref
Hongjae Kang, Jeongmoo Huh & Sejin Kwon. (2017) Measuring the Reaction Rate of Hypergolic Propellants with a Microelectromechanical Systems Reactor. Journal of Spacecraft and Rockets 54:2, pages 337-342.
Crossref
Sen Li & Xiaolin Wei. (2016) Ignition Delay Characteristics of Kerosene with Decomposed Hydrogen Peroxide. Journal of Propulsion and Power 32:2, pages 431-438.
Crossref
Nick Zarbo, Hatem Belal & Timothee L. Pourpoint. (2015) Effect of Water and Humidity on Hypergolic Propellant Ignition Delay. Effect of Water and Humidity on Hypergolic Propellant Ignition Delay.
Tony Yuan, Yu-Ta Chen & Berlin Huang. (2015) Semi-Hypergolic Kerosene/Hydrogen Peroxide Fuel System and Its Auto-Ignition Injector Design. Semi-Hypergolic Kerosene/Hydrogen Peroxide Fuel System and Its Auto-Ignition Injector Design.
Jacob D. Dennis, Steven F. Son & Timothée L. Pourpoint. (2015) Critical Ignition Criteria for Monomethylhydrazine and Red Fuming Nitric Acid. Journal of Propulsion and Power 31:4, pages 1184-1192.
Crossref
Stephen M. Davis & Nadir Yilmaz. (2014) Advances in Hypergolic Propellants: Ignition, Hydrazine, and Hydrogen Peroxide Research. Advances in Aerospace Engineering 2014, pages 1-9.
Crossref
Samuel Hassid & Benveniste Natan. (2013) Thermal Diffusion Controlled Ignition of Hypergolic Gel Propellants. Journal of Propulsion and Power 29:6, pages 1337-1342.
Crossref
Jacob Dennis, Steven Son & Timothee Pourpoint. (2012) Critical Ignition Criteria for Monomethylhydrazine and Red Fuming Nitric Acid in an Impinging Jet Apparatus. Critical Ignition Criteria for Monomethylhydrazine and Red Fuming Nitric Acid in an Impinging Jet Apparatus.
Natan Petrutik, Ilia Kaminker, Eli Flaxer, Daniel Shem-Tov, Tsabar Giladi, Yossi Bar-Bechor, Jagadish Das & Michael Gozin. (2022) Greener Space Propulsion – Janus-Type Hypergolic Fuels for Hybrid Systems Using H2o2 and Han-Based Oxidizers. SSRN Electronic Journal.
Crossref

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.