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Wu J, Bruce FNO, Bai X, Ren X, Li Y. 2023. Insights into the reaction kinetics of hydrazine-based fuels: a comprehensive review of theoretical and experimental methods. Energies 16:6006

Eberstein IJ, Glassman I. 1965. The gas-phase decomposition of hydrazine and its methyl derivatives. Symposium (International) on Combustion 10:365−374

Vaghjiani GL. 1997. UV absorption cross sections, laser photodissociation product quantum yields, and reactions of H atoms with methylhydrazines at 298 K. The Journal of Physical Chemistry A 101:4167−4171

Vaghjiani GL. 2001. Kinetics of OH reactions with N₂H₄, CH₃NHNH₂ and (CH₃)₂NNH₂ in the gas phase. International Journal of Chemical Kinetics 33:354−362

Catoire L, Bassin X, Dupre G, Paillard C. 1994. Shock tube study of ignition delays and detonation of gaseous monomethylhydrazine/oxygen mixtures. Combustion and Flame 99:573−580

Catoire L, Bassin X, Ingignoli W, Dupre G, Paillard C. 1997. Shock tube study of the effect of nitrogen or hydrogen on ignition delays in mixtures of monomethylhydrazine + oxygen + argon. Combustion and Flame 109:37−42

Liu WG, Wang S, Dasgupta S, Thynell ST, Goddard WA III, et al. 2013. Experimental and quantum mechanics investigations of early reactions of monomethylhydrazine with mixtures of NO₂ and N₂O₄. Combustion and Flame 160:970−981

Catoire L, Bassin X, Dupre G, Paillard C. 1996. Experimental study and kinetic modeling of the thermal decomposition of gaseous monomethylhydrazine. Application to detonation sensitivity. Shock Waves 6:139−146

Diévart P, Catoire L. 2020. Contributions of experimental data obtained in concentrated mixtures to kinetic studies: application to monomethylhydrazine pyrolysis. The Journal of Physical Chemistry A 124:6214−6236

Sun H, Law CK. 2007. Thermochemical and kinetic analysis of the thermal decomposition of monomethylhydrazine: an elementary reaction mechanism. The Journal of Physical Chemistry A 111:3748−3760

Ding N, Luo Q, Li QS. 2011. Ab initio study of the F + CH₃NHNH₂ reaction mechanism. The Journal of Physical Chemistry A 115:805−814

Sun H, Zhang P, Law CK. 2012. Gas-phase kinetics study of reaction of OH radical with CH₃NHNH₂ by second-order multireference perturbation theory. The Journal of Physical Chemistry A 116:5045−5056

Wang L, Zhao Y, Wen J, Zhang J. 2012. Mechanisms and kinetics of hydrogen abstraction of methylhydrazine and deuterated methylhydrazine with H/D atoms. Theoretical Chemistry Accounts 132:1321

Wang L, Wang N, He H, Zhang J. 2014. Theoretical study on the reactions of CH₃NHNH₂ with ground state O(³P) atom and excited state O(¹D) atom. Molecular Physics 112:1600−1607

Valadbeigi Y, Farrokhpour H. 2015. Kinetics, mechanism and thermodynamics of reactions of CH₃NHNH₂ with OOH. Molecular Physics 113:577−583

Bai J, Liu D, Zhang L, Zhang P. 2024. Theoretical study of the second- and third-H-abstraction reactions of monomethylhydrazine and nitrogen dioxide and its application to hypergolic ignition modeling. Combustion and Flame 268:113617

Sun H, Vaghjiani GL, Law CK. 2020. Ab initio kinetics of methylamine radical thermal decomposition and H-abstraction from monomethylhydrazine by H-atom. The Journal of Physical Chemistry A 124:3747−3753

Ren X, Chen H, Qu B, Fu X, Liu S, et al. 2023. Ab initio kinetics of H-atom abstraction from monomethylhydrazine. Combustion and Flame 257:112998

Milyushkin AL, Karnaeva AE. 2023. Unsymmetrical dimethylhydrazine transformation products: a review. Science of the Total Environment 891:164367

Gray P, Spencer M. 1964. Combustion of unsymmetrical dimethyl hydrazine supported by oxygen or nitrous oxide: laminar flame propagation. Combustion and Flame 8:29−36

Kumar RR, Bhaskaran KA. 1976. Shock tube study of the effect of unsymmetric dimethyl hydrazine on the ignition delay of methane oxygen-argon mixtures. Combustion and Flame 27:107−112

Bhaskaran KA, Gupta MC, Just T. 1973. Shock tube study of the effect of unsymmetric dimethyl hydrazine on the ignition characteristics of hydrogen-air mixtures. Combustion and Flame 21:45−48

Tang Y, Lu C, Han Z, Zhai F, Fu Z. 2019. Theoretical investigations on mechanisms and kinetics of OH + (CH₃)₂NNH₂ reaction in the atmosphere. Theoretical Chemistry Accounts 138:45

Kanno N, Kito T. 2020. Theoretical study on the hydrogen abstraction reactions from hydrazine derivatives by H atom. International Journal of Chemical Kinetics 52:548−555

Bai X, Ren X, He R, Bruce FNO, Tong Y, et al. 2025. A theoretical combustion kinetic study of unsymmetrical dimethylhydrazine: H-atom abstraction and reactions on the potential energy surface of C₂H₇N₂ radicals. The Journal of Physical Chemistry A 129:8509−8518

Ma Z, Xing L, Lian L, Li H, Liu M, et al. 2025. Theoretical investigation on the reaction kinetics of NO₂ with cyclopentane, cyclopentene and cyclohexane. Fuel 382:133747

He Y, Xing L, Zhu Q, Lian L, Wang X, et al. 2023. Theoretical kinetic study on hydrogen abstraction reactions from n-pentane by NO₂. The Journal of Physical Chemistry A 127:10243−10252

Yan J, Wang P, Yan T, Ao C, Zhang L, et al. 2024. A theoretical calculation and kinetic modeling analysis of H-abstraction from 1-octene for subsequent isomerization and β-dissociation. International Journal of Hydrogen Energy 55:1028−1036

Zhao Y, Truhlar DG. 2008. The M06 suite of density functionals for main group thermochemistry, thermochemical kinetics, noncovalent interactions, excited states, and transition elements: two new functionals and systematic testing of four M06-class functionals and 12 other functionals. Theoretical Chemistry Accounts 120:215−241

Neese F. 2012. The ORCA program system. WIREs Computational Molecular Science 2:73−78

Xing L, Cui J, Lian L, Wang J, Wang H, et al. 2023. Ab initio kinetics of OH-initiated reactions of 2-furfuryl alcohol. Fuel 338:127325

Bai J, Liu D, Zhang L, Zhou L, Zhang P. 2025. Towards hypergolic ignition modeling of monomethylhydrazine and nitrogen dioxide: ab initio chemical kinetics of CH₃NH/CH₂NH₂/CH₂NH and nitrogen dioxide. Combustion and Flame 275:114034

Giri BR, Mai TVT, Shrestha KP, Giri S, Naik RT, et al. 2025. Theoretical kinetic study of NH₂ reactions with dimethyl ether and diethyl ether: implications for kinetic modeling. International Journal of Chemical Kinetics 57:353−363

Bao JL, Zheng J, Alecu IM, Lynch BJ, Zhao Y, et al. n.d. Database of frequency scale factors for electronic model chemistries (Version 3 Beta 2). https://comp.chem.umn.edu/freqscale/version3b2.htm

Duan Y, Ren Z, Huang Z, Han D. 2022. Theoretical study on isomerization, decomposition and ring-closure reaction kinetics of methyl pentanoate radicals. Combustion and Flame 237:111848

Miller JA, Klippenstein SJ. 2003. From the multiple-well master equation to phenomenological rate coefficients: reactions on a C₃H₄ potential energy surface. The Journal of Physical Chemistry A 107:2680−2692

Zhao Q, Zhang Y, Curran HJ, Huang Z. 2022. Theoretical correction on the existing understanding for hydroper-oxymethyl formate dissociation in DME low temperature oxidation. Combustion and Flame 241:112065

Lee TJ, Taylor PR. 1989. A diagnostic for determining the quality of single-reference electron correlation methods. International Journal of Quantum Chemistry 36:199−207

Frisch MJ, Trucks GW, Schlegel HB, Scuseria GE, Robb MA, et al. 2013. Gaussian 09, Revision D. 01. Wallingford CT: Gaussian, Inc. https://gaussian.com

Fang Q, Fang J, Li W, Lian T, Zhao L, et al. 2024. Unraveling combustion chemistry of dimethyldiethoxysilane. I. A comprehensive pyrolysis investigation with insight into ethanol formation mechanism in combustion of ethoxysilane flame synthesis precursors. Combustion and Flame 270:113794

Werner HJ, Knowles PJ, Knizia G, Manby FR, Schütz M. 2012. Molpro: a general-purpose quantum chemistry program package. WIREs Computational Molecular Science 2:242−253

Klippenstein SJ, Cline JI. 1995. Classical phase space theory for product state distributions with application to the v–j vector correlation. The Journal of Chemical Physics 103:5451−5460

Cavallotti C, Pelucchi M, Georgievskii Y, Klippenstein SJ. 2019. EStokTP: electronic structure to temperature- and pressure-dependent rate constants − a code for automatically predicting the thermal kinetics of reactions. Journal of Chemical Theory and Computation 15:1122−1145

East ALL, Radom L. 1997. Ab initio statistical thermodynamical models for the computation of third-law entropies. The Journal of Chemical Physics 106:6655−6674

Eckart C. 1930. The penetration of a potential barrier by electrons. Physical Review 35:1303−1309

Miller JA, Klippenstein SJ. 2006. Master equation methods in gas phase chemical kinetics. The Journal of Physical Chemistry A 110:10528−10544

Zhang P, Klippenstein SJ, Sun H, Law CK. 2011. Ab initio kinetics for the decomposition of monomethylhydrazine (CH₃NHNH₂). Proceedings of the Combustion Institute 33:425−432

Mourits FM, Rummens FHA. 1977. A critical evaluation of Lennard – Jones and Stockmayer potential parameters and of some correlation methods. Canadian Journal of Chemistry 55:3007−3020

Georgievskii Y, Miller JA, Burke MP, Klippenstein SJ. 2013. Reformulation and solution of the master equation for multiple-well chemical reactions. The Journal of Physical Chemistry A 117:12146−12154

Klippenstein SJ, Harding LB, Davis MJ, Tomlin AS, Skodje RT. 2011. Uncertainty driven theoretical kinetics studies for CH₃OH ignition: HO₂ + CH₃OH and O₂ + CH₃OH. Proceedings of the Combustion Institute 33:351−357

Wang S, Zhang Y, Fu L, Ning H. 2025. Theoretical study on the combustion kinetics of trimethylamine and the key intermediate N-methylmethanimine. Combustion and Flame 272:113860