Back Article

Kobayashi H, Hayakawa A, Somarathne KA, Okafor EC. 2019. Science and technology of ammonia combustion. Proceedings of the Combustion Institute 37(1):109−133

Han X, Wang Z, He Y, Zhu Y, Cen K. 2020. Experimental and kinetic modeling study of laminar burning velocities of NH₃/syngas/air premixed flames. Combustion and Flame 213:1−13

Reiter AJ, Kong SC. 2011. Combustion and emissions characteristics of compression-ignition engine using dual ammonia-diesel fuel. Fuel 90(1):87−97

Pacheco GP, Rocha RC, Franco MC, Mendes MAA, Fernandes EC, et al. 2021. Experimental and kinetic investigation of stoichiometric to rich NH₃/H₂/air flames in a swirl and bluff-body stabilized burner. Energy & Fuels 35(9):7201−7216

Tang G, Jin P, Bao Y, Chai WS, Zhou L. 2021. Experimental investigation of premixed combustion limits of hydrogen and methane additives in ammonia. International Journal of Hydrogen Energy 46(39):20765−20776

Kim HK, Ku JW, Ahn YJ, Kim YH, Kwon OC. 2021. Effects of O₂ enrichment on NH₃/air flame propagation and emissions. International Journal of Hydrogen Energy 46(46):23916−23926

Chen DN, Li J, Huang HY, Chen Y, He ZH, et al. 2020. Progress on ammonia combustion and reaction mechanism. Chemistry 83(6):508−515 (in Chinese)

Takizawa K, Takahashi A, Tokuhashi K, Kondo S, Sekiya A. 2008. Burning velocity measurements of nitrogen-containing compounds. Journal of Hazardous Materials 155(1−2):144−152

Mei B, Zhang X, Ma S, Cui M, Guo H, et al. 2019. Experimental and kinetic modeling investigation on the laminar flame propagation of ammonia under oxygen enrichment and elevated pressure conditions. Combustion and Flame 210:236−246

Lhuillier C, Brequigny P, Lamoureux N, Contino F, Mounaïm-Rousselle C. 2020. Experimental investigation on laminar burning velocities of ammonia/hydrogen/air mixtures at elevated temperatures. Fuel 263:116653

Hayakawa A, Goto T, Mimoto R, Arakawa Y, Kudo T, et al. 2015. Laminar burning velocity and Markstein length of ammonia/air premixed flames at various pressures. Fuel 159:98−106

Chen X, Liu Q, Jing Q, Mou Z, Shen Y, et al. 2021. Flame front evolution and laminar flame parameter evaluation of buoyancy-affected ammonia/air flames. International Journal of Hydrogen Energy 46(77):38504−38518

Shrestha KP, Lhuillier C, Barbosa AA, Brequigny P, Contino F, et al. 2021. An experimental and modeling study of ammonia with enriched oxygen content and ammonia/hydrogen laminar flame speed at elevated pressure and temperature. Proceedings of the Combustion Institute 38(2):2163−2174

Kanoshima R, Hayakawa A, Kudo T, Okafor EC, Colson S, et al. 2022. Effects of initial mixture temperature and pressure on laminar burning velocity and Markstein length of ammonia/air premixed laminar flames. Fuel 310:122149

Liang B, Gao W, Zhang K, Li Y. 2023. Ammonia-air combustion and explosion characteristics at elevated temperature and elevated pressure. International Journal of Hydrogen Energy 48(53):20225−20237

Alvarez LF, Shaffer J, Dumitrescu CE, Askari O. 2024. Laminar burning velocity of Ammonia/Air mixtures at high pressures. Fuel 363:130986

Zhou S, Cui B, Yang W, Tan H, Wang J, et al. 2023. An experimental and kinetic modeling study on NH₃/air, NH₃/H₂/air, NH₃/CO/air, and NH₃/CH₄/air premixed laminar flames at elevated temperature. Combustion and Flame 248:112536

Kohansal M, Kiani M, Masoumi S, Nourinejad S, Ashjaee M, et al. 2023. Experimental and numerical investigation of NH₃/CH₄ mixture combustion properties under elevated initial pressure and temperature. Energy & Fuels 37(14):10681−10696

Liu B, Hu E, Yin G, Huang Z. 2023. Experimental and kinetic study on laminar burning velocities of ammonia/ethylene/air premixed flames under high temperature and elevated pressure. Combustion and Flame 251:112707

Hu E, Li X, Meng X, Chen Y, Cheng Y, et al. 2015. Laminar flame speeds and ignition delay times of methane–air mixtures at elevated temperatures and pressures. Fuel 158:1−10

Mathieu O, Petersen EL. 2015. Experimental and modeling study on the high-temperature oxidation of Ammonia and related NO_x chemistry. Combustion and Flame 162(3):554−570

Shu B, Vallabhuni SK, He X, Issayev G, Moshammer K, et al. 2019. A shock tube and modeling study on the autoignition properties of ammonia at intermediate temperatures. Proceedings of the Combustion Institute 37(1):205−211

He X, Shu B, Nascimento D, Moshammer K, Costa M, et al. 2019. Auto-ignition kinetics of ammonia and ammonia/hydrogen mixtures at intermediate temperatures and high pressures. Combustion and Flame 206:189−200

Dai L, Gersen S, Glarborg P, Levinsky H, Mokhov A. 2020. Experimental and numerical analysis of the autoignition behavior of NH₃ and NH₃/H₂ mixtures at high pressure. Combustion and Flame 215:134−144

Chen J, Jiang X, Qin X, Huang Z. 2021. Effect of hydrogen blending on the high temperature auto-ignition of ammonia at elevated pressure. Fuel 287:119563

Peng Y, Ranjan D, Sun W. 2023. A shock tube study of fuel concentration effect on high-pressure autoignition delay of ammonia. Applications in Energy and Combustion Science 16:100202

Dagaut P. 2022. On the oxidation of ammonia and mutual sensitization of the oxidation of No and ammonia: experimental and kinetic modeling. Combustion Science and Technology 194(1):117−129

Manna MV, Sabia P, Ragucci R, de Joannon M. 2020. Oxidation and pyrolysis of ammonia mixtures in model reactors. Fuel 264:116768

Osipova KN, Zhang X, Sarathy SM, Korobeinichev OP, Shmakov AG. 2022. Ammonia and ammonia/hydrogen blends oxidation in a jet-stirred reactor: experimental and numerical study. Fuel 310:122202

Sabia P, Manna MV, Cavaliere A, Ragucci R, de Joannon M. 2020. Ammonia oxidation features in a Jet Stirred Flow Reactor. The role of NH2 chemistry. Fuel 276:118054

Song Y, Hashemi H, Christensen JM, Zou C, Marshall P, et al. 2016. Ammonia oxidation at high pressure and intermediate temperatures. Fuel 181:358−365

Otomo J, Koshi M, Mitsumori T, Iwasaki H, Yamada K. 2018. Chemical kinetic modeling of ammonia oxidation with improved reaction mechanism for ammonia/air and ammonia/hydrogen/air combustion. International Journal of Hydrogen Energy 43(5):3004−3014

Zhang X, Moosakutty SP, Rajan RP, Younes M, Sarathy SM. 2021. Combustion chemistry of ammonia/hydrogen mixtures: jet-stirred reactor measurements and comprehensive kinetic modeling. Combustion and Flame 234:111653

Shrestha KP, Giri BR, Pelé R, Aljohani K, Brequigny P, et al. 2025. A comprehensive chemical kinetic modeling and experimental study of NH₃–methanol/ethanol combustion towards net-zero CO₂ emissions. Combustion and Flame 274:113954

Bertolino A, Fürst M, Stagni A, Frassoldati A, Pelucchi M, et al. 2021. An evolutionary, data-driven approach for mechanism optimization: theory and application to ammonia combustion. Combustion and Flame 229:111366

Wang Z, Ji C, Zhang T, Wang D, Zhai Y, et al. 2023. Experimental and numerical study on laminar premixed NH₃/H₂/O₂/air flames. International Journal of Hydrogen Energy 48(39):14885−14895

Zhu Y, Curran HJ, Girhe S, Murakami Y, Pitsch H, et al. 2024. The combustion chemistry of ammonia and ammonia/hydrogen mixtures: a comprehensive chemical kinetic modeling study. Combustion and Flame 260:113239

Zhang Y, Cui LM, Niu T, Hong DK. 2024. Study on the synergistic mechanism of co-pyrolysis of coal and ammonia based on ReaxFF molecular dynamics method. Journal of Engineering for Thermal Energy and Power 39(6):98−106 (in Chinese)

Huang FQ, Wang J, Jiang XZ. 2023. Reactive molecular dynamics of the effect of H₂ on the combustion of NH₃ in air. Advances in New and Renewable Energy 11(5):404−410 (in Chinese)

Zhang Q, Guo L, Cai X, Shan S, Li K, et al. 2021. Chemical effect of CH₄ on NH₃ combustion in an O₂/N₂ environment via ReaxFF. Energy & Fuels 35(13):10918−10928

Hong D, Yuan L, Wang C. 2022. Competition between NH₃-O₂ reaction and char-O₂ reaction and its influence on NO generation and reduction during char/NH₃ co-combustion: reactive molecular dynamic simulations. Fuel 324:124666

Guo Y, Shi H, Liu H, Xie Y, Guan Y. 2023. Reactive molecular dynamics simulation and chemical kinetic modeling of ammonia/methane co-combustion. Fuel 354:129341

Wang J, Jiang XZ, Luo KH. 2023. Exploring reaction mechanism for ammonia/methane combustion via reactive molecular dynamics simulations. Fuel 331:125806

Hong D, Yuan L, Wang C. 2024. The influence of NH₃ on coal combustion kinetics during coal/NH₃ cocombustion: experiments and ReaxFF MD simulations. Energy & Fuels 38(10):9120−9129

Wang Y, Sun J, Liu Q, Chen L, Gu M, et al. 2024. NO_x formation mechanism of plasma assisted ammonia combustion: a reactive molecular dynamics study. Energy 293(C):130706

van Duin ACT, Dasgupta S, Lorant F, Goddard WA. 2001. ReaxFF: a reactive force field for hydrocarbons. The Journal of Physical Chemistry A 105(41):9396−9409

Senftle TP, Hong S, Islam MM, Kylasa SB, Zheng Y, et al. 2016. The ReaxFF reactive force-field: development, applications and future directions. npj Computational Materials 2:15011

Aktulga HM, Fogarty JC, Pandit SA, Grama AY. 2012. Parallel reactive molecular dynamics: numerical methods and algorithmic techniques. Parallel Computing 38(4−5):245−259

Stukowski A. 2010. Visualization and analysis of atomistic simulation data with OVITO–the Open Visualization Tool. Modelling and Simulation in Materials Science and Engineering 18(1):015012

Liu Q, Huang W, Liu B, Wang PC, Chen HB. 2021. Gamma radiation chemistry of polydimethylsiloxane foam in radiation-thermal environments: experiments and simulations. ACS Applied Materials & Interfaces 13(34):41287−41302

Zhang L, van Duin ACT, Zybin SV, Goddard WA, III. 2009. Thermal decomposition of hydrazines from reactive dynamics using the ReaxFF reactive force field. The Journal of Physical Chemistry B 113(31):10770−10778

Goodwin DG, Speth RL, Moffat HK, Weber BW. 2018. Cantera: an object-oriented software toolkit for chemical kinetics, thermodynamics, and transport processes. Version 2.4.0 ed. doi: 10.5281/zenodo.742000

Hashemi H, Christensen JM, Gersen S, Glarborg P. 2015. Hydrogen oxidation at high pressure and intermediate temperatures: experiments and kinetic modeling. Proceedings of the Combustion Institute 35(1):553−560

Meng Q, Lei L, Lee J, Burke MP. 2023. On the role of HNNO in NO_x formation. Proceedings of the Combustion Institute 39(1):551−560

National Institute of Standards and Technology. 2026. Kinetics database. https://kinetics.nist.gov

Miller JA, Klippenstein SJ. 2000. Theoretical considerations in the NH₂ + NO reaction. The Journal of Physical Chemistry A 104(10):2061−2069

Yokoyama K, Sakane Y, Fueno T. 1991. Formations of OH(X²II, A²Σ⁺) in the reaction of NH(³Σ^–) with NO in incident shock waves. Bulletin of the Chemical Society of Japan 64(6):1738−1742

Li Y, Bi M, Li B, Gao W. 2018. Explosion behaviors of ammonia–air mixtures. Combustion Science and Technology 190(10):1804−1816