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Combustion Science and Technology Volume 158, 2000 - Issue 1
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Original Articles

Kinetic Modeling of Carbon Suboxide Thermal Decomposition and Formation of Soot-Like Particles Behind Shock Waves

J. SOJKA IWR, Universitat Heidelberg, Im Neuenheimer Feld 368, Heidelberg, D-69120, Germany
,
J. WARNATZ IWR, Universitat Heidelberg, Im Neuenheimer Feld 368, Heidelberg, D-69120, GermanyView further author information
,
P.A. VLASOV Russian Academy of Sciences, Semenov Institute of Chemical Physics, Kosygin str. 4, Moscow, 117977, Russia
&
I.S. ZASLONKO Russian Academy of Sciences, Semenov Institute of Chemical Physics, Kosygin str. 4, Moscow, 117977, RussiaView further author information
Pages 439-460 | Received 01 May 2000, Published online: 15 May 2007

Citations (19)

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J.Z. Wen, M.J. Thomson & M.F. Lightstone. (2006) Numerical study of carbonaceous nanoparticle formation behind shock waves. Combustion Theory and Modelling 10:2, pages 257-272.
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I. NAYDENOVA, M. NULLMEIER, J. WARNATZ & P.A. VLASOV. (2004) DETAILED KINETIC MODELING OF SOOT FORMATION DURING SHOCK-TUBE PYROLYSIS OF C6H6: DIRECT COMPARISON WITH THE RESULTS OF TIME-RESOLVED LASER-INDUCED INCANDESCENCE (LII) AND CW-LASER EXTINCTION MEASUREMENTS. Combustion Science and Technology 176:10, pages 1667-1703.
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Articles from other publishers (17)

A V Eremin & V E Fortov. (2021) Detonation wave of condensation. Physics-Uspekhi 64:11, pages 1073-1093.
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S. K. Yadav, P. Shukla, Manish Joshi, Arshad Khan, A. Kaushik, Ajit Kumar Jha, B. K. Sapra & R. S. Singh. (2020) Emission characteristics of ultrafine particles from bare and Al2O3 coated graphite for high temperature applications. Scientific Reports 10:1.
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S Srinath & K P J Reddy. (2015) Large carbon cluster thin film gauges for measuring aerodynamic heat transfer rates in hypersonic shock tunnels. Measurement Science and Technology 26:2, pages 025901.
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A. Emelianov, A. Eremin, E. Gurentsov, E. Mikheyeva & M. Yurischev. (2015) Experimental study of soot size decrease with pyrolysis temperature rise. Proceedings of the Combustion Institute 35:2, pages 1753-1760.
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Mohammad Aghsaee, Steffen H. Dürrstein, Jürgen Herzler, Heidi Böhm, Mustapha Fikri & Christof Schulz. (2014) Influence of molecular hydrogen on acetylene pyrolysis: Experiment and modeling. Combustion and Flame 161:9, pages 2263-2269.
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J. Marquetand, M. Fischer, I. Naydenova & U. Riedel. 2013. Flow and Combustion in Advanced Gas Turbine Combustors. Flow and Combustion in Advanced Gas Turbine Combustors 205 233 .
Heidi Böhm, Alexander Emelianov, Alexander Eremin, Christof Schulz & Helga Jander. (2012) On the effect of molecular and hydrocarbon-bonded hydrogen on carbon particle formation in C3O2 pyrolysis behind shock waves. Combustion and Flame 159:3, pages 932-939.
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Alexander V. Eremin. (2012) Formation of carbon nanoparticles from the gas phase in shock wave pyrolysis processes. Progress in Energy and Combustion Science 38:1, pages 1-40.
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M. Aghsaee, H. Böhm, S. H. Dürrstein, M. Fikri & C. Schulz. (2012) Experimental and modeling study of carbon suboxide decomposition behind reflected shock waves. Phys. Chem. Chem. Phys. 14:3, pages 1246-1252.
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A. Emelianov, A. Eremin, H. Jander & H.Gg. Wagner. (2011) Carbon condensation wave in C3O2 and C2H2 initiated by a shock wave. Proceedings of the Combustion Institute 33:1, pages 525-532.
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A. V. Emel’yanov, A. V. Eremin & V. E. Fortov. (2010) Formation of a detonation wave in the process of chemical condensation of carbon nanoparticles. Journal of Engineering Physics and Thermophysics 83:6, pages 1197-1209.
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A Eremin, E Gurentsov, M Hofmann, B Kock & C Schulz. (2006) Nanoparticle formation from supersaturated carbon vapour generated by laser photolysis of carbon suboxide. Journal of Physics D: Applied Physics 39:20, pages 4359-4365.
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J. Z. Wen, M. J. Thomson, M. F. Lightstone & S. N. Rogak. (2006) Detailed Kinetic Modeling of Carbonaceous Nanoparticle Inception and Surface Growth during the Pyrolysis of C 6 H 6 behind Shock Waves . Energy & Fuels 20:2, pages 547-559.
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A. Emelianov, A. Eremin, H. Jander & H. Gg. Wagner. (2003) To the Temperature Dependence of Carbon Particle Formation in Shock Wave Pyrolysis Processes. Zeitschrift für Physikalische Chemie 217:7, pages 893-910.
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J. Deppe, A. Emelianov, A. Eremin & H.Gg. Wagner. (2002) Formation of Carbon Nanoparticle in Carbon Suboxide Pyrolysis behind Shock Waves. Zeitschrift für Physikalische Chemie 216:5.
Crossref
A. Emelianov, A. Eremin, H. Jander, H.GG. Wagner & Ch. Borchers. (2002) Spectral and structural properties of carbon nanoparticle forming in C3O2 and C2H2 pyrolysis behind shock waves. Proceedings of the Combustion Institute 29:2, pages 2351-2357.
Crossref
P.A. Vlasov & J. Warnatz. (2002) Detailed kinetic modeling of soot formation in hydrocarbon pyrolysis behind shock waves. Proceedings of the Combustion Institute 29:2, pages 2335-2341.
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