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Combustion Science and Technology Volume 123, 1997 - Issue 1-6
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Original Articles

Formation and Growth of Sio2 Particlesin Low Pressure H2/O2/Ar Flames Doped with Sih4

D. Lindackers Institut für Verbrennung und Gasdynamik, Gerhard-Mercetor-Universität Duisburg, 47048 Duisburg, Germany
,
M. G. D. Strecker Institut für Verbrennung und Gasdynamik, Gerhard-Mercetor-Universität Duisburg, 47048 Duisburg, Germany
,
P. Roth Institut für Verbrennung und Gasdynamik, Gerhard-Mercetor-Universität Duisburg, 47048 Duisburg, Germany
,
C. Janzen Department of Chemical Engineering, Center for Aerosol Processes, University of Cincinnati, Cincinnati, OH 45221, USA
&
S. E. Pratsinis Department of Chemical Engineering, Center for Aerosol Processes, University of Cincinnati, Cincinnati, OH 45221, USA
Pages 287-315 | Received 15 Jul 1996, Published online: 22 Sep 2010

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C. Weise, A. Faccinetto, S. Kluge, T. Kasper, H. Wiggers, C. Schulz, I. Wlokas & A. Kempf. (2013) Buoyancy induced limits for nanoparticle synthesis experiments in horizontal premixed low-pressure flat-flame reactors. Combustion Theory and Modelling 17:3, pages 504-521.
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Neal Morgan, Clive Wells, Markus Kraft & Wolfgang Wagner. (2005) Modelling nanoparticle dynamics: coagulation, sintering, particle inception and surface growth. Combustion Theory and Modelling 9:3, pages 449-461.
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C. L. YEH, E. ZHAO & H. K. MA. (2001) AN EXPERIMENTAL INVESTIGATION OF COMBUSTION SYNTHESIS OF SILICON DIOXIDE (SiO2) PARTICLES IN PREMIXED FLAMES. Combustion Science and Technology 173:1, pages 25-46.
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Articles from other publishers (48)

Stefan Andersson. (2023) Mechanisms and Thermochemistry of Reactions of SiO and Si 2 O 2 with OH and H 2 O . The Journal of Physical Chemistry A 127:18, pages 4015-4026.
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Stefan Andersson, David Gobrecht & Rosendo Valero. (2023) Mechanisms of SiO oxidation: Implications for dust formation. Frontiers in Astronomy and Space Sciences 10.
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Tianyi Wu, Sheng Chen, Pinzhuo Chen & Shuiqing Li. (2023) Clustering and collision of Brownian particles in homogeneous and isotropic turbulence. Journal of Aerosol Science 169, pages 106134.
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Jingxian Xia, Yan Zhang, Qilong Fang, Bowen Mei, Jianguo Zhang, Wei Li & Yuyang Li. (2023) A case study on laminar flame propagation of flame synthesis precursors using spherically propagating flame: Tetramethylsilane and its alkane counterpart. Proceedings of the Combustion Institute 39:2, pages 1555-1566.
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Weijia Qian, Andreas Kronenburg, Xin Hui, Yuzhen Lin & Maximilian Karsch. (2022) Effects of agglomerate characteristics on their collision kernels in the free molecular regime. Journal of Aerosol Science 159, pages 105868.
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Florian Meierhofer & Udo Fritsching. (2021) Synthesis of Metal Oxide Nanoparticles in Flame Sprays: Review on Process Technology, Modeling, and Diagnostics. Energy & Fuels 35:7, pages 5495-5537.
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Y. Karakaya, S. Kluge, H. Wiggers, C. Schulz & T. Kasper. (2021) Investigation of the combustion of iron pentacarbonyl and the formation of key intermediates in iron oxide synthesis flames. Chemical Engineering Science 230, pages 116169.
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H. Janbazi, Y. Karakaya, T. Kasper, C. Schulz, I. Wlokas & S. Peukert. (2019) Development and evaluation of a chemical kinetics reaction mechanism for tetramethylsilane-doped flames. Chemical Engineering Science 209, pages 115209.
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Y. Karakaya, S. Peukert & T. Kasper. (2018) Mass Spectrometric Study on the Combustion of Tetramethylsilane and the Formation of Silicon Oxide Clusters in Premixed Laminar Low-Pressure Synthesis Flames. The Journal of Physical Chemistry A 122:36, pages 7131-7141.
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Robin S. M. Chrystie, Omid M. Feroughi, Thomas Dreier & Christof Schulz. (2017) SiO multi-line laser-induced fluorescence for quantitative temperature imaging in flame-synthesis of nanoparticles. Applied Physics B 123:4.
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Omid M. Feroughi, Lei Deng, Sebastian Kluge, Thomas Dreier, Hartmut Wiggers, Irenäus Wlokas & Christof Schulz. (2017) Experimental and numerical study of a HMDSO-seeded premixed laminar low-pressure flame for SiO2 nanoparticle synthesis. Proceedings of the Combustion Institute 36:1, pages 1045-1053.
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Shuiqing Li, Yihua Ren, Pratim Biswas & Stephen D. Tse. (2016) Flame aerosol synthesis of nanostructured materials and functional devices: Processing, modeling, and diagnostics. Progress in Energy and Combustion Science 55, pages 1-59.
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Mari K. Næss, Jan Erik Olsen, Stefan Andersson & Gabriella Tranell. (2014) Parameters Affecting the Rate and Product of Liquid Silicon Oxidation. Oxidation of Metals 82:5-6, pages 395-413.
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O. M. Feroughi, A. Langer, T. Dreier & C. Schulz. (2014) Spatially-resolved measurements of gas-phase temperature and SiO concentration in a low-pressure nanoparticle synthesis reactor using laser-induced fluorescence. Spatially-resolved measurements of gas-phase temperature and SiO concentration in a low-pressure nanoparticle synthesis reactor using laser-induced fluorescence.
Alexey Fomin, Marina Poliak, Igor Rahinov, Vladimir Tsionsky & Sergey Cheskis. (2013) Combined particle mass spectrometer – Quartz crystal microbalance apparatus for in situ nanoparticle monitoring during flame assisted synthesis. Combustion and Flame 160:10, pages 2131-2140.
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Hartmut Wiggers, Mustapha Fikri, Irenaeus Wlokas, Paul Roth & Christof Schulz. 2012. Nanoparticles from the Gasphase. Nanoparticles from the Gasphase 3 48 .
C. Hecht, H. Yang, T. Dreier & C. Schulz. (2010) In-Situ Laser Diagnostics of Temperature, Intermediate Species Concentration and Particle Sizes in Gas-Phase Nanoparticle Synthesis. In-Situ Laser Diagnostics of Temperature, Intermediate Species Concentration and Particle Sizes in Gas-Phase Nanoparticle Synthesis.
S. Staude, C. Hecht, I. Wlokas, C. Schulz & Burak Atakan. (2009) Experimental and Numerical Investigation of Fe(CO) 5 Addition to a Laminar Premixed Hydrogen/Oxygen/Argon Flame . Zeitschrift für Physikalische Chemie 223:4-5, pages 639-649.
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B. Buesser, M.C. Heine & S.E. Pratsinis. (2009) Coagulation of highly concentrated aerosols. Journal of Aerosol Science 40:2, pages 89-100.
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C. Hecht, H. Kronemayer, T. Dreier, H. Wiggers & C. Schulz. (2008) Imaging measurements of atomic iron concentration with laser-induced fluorescence in a nanoparticle synthesis flame reactor. Applied Physics B 94:1, pages 119-125.
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Norma Yadira Mendoza Gonzalez, Mbark El Morsli & Pierre Proulx. (2008) Production of Nanoparticles in Thermal Plasmas: A Model Including Evaporation, Nucleation, Condensation, and Fractal Aggregation. Journal of Thermal Spray Technology 17:4, pages 533-550.
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Juncheng Hu, Lifang Chen & Ryan Richards. 2008. Metal Oxide Catalysis. Metal Oxide Catalysis 613 663 .
H. Kronemayer, P. Ifeacho, C. Hecht, T. Dreier, H. Wiggers & C. Schulz. (2007) Gas-temperature imaging in a low-pressure flame reactor for nano-particle synthesis with multi-line NO-LIF thermometry. Applied Physics B 88:3, pages 373-377.
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Paul Roth. (2007) Particle synthesis in flames. Proceedings of the Combustion Institute 31:2, pages 1773-1788.
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Neal Morgan, Markus Kraft, Michael Balthasar, David Wong, Michael Frenklach & Pablo Mitchell. (2007) Numerical simulations of soot aggregation in premixed laminar flames. Proceedings of the Combustion Institute 31:1, pages 693-700.
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Teresa Moore, Brian Brady & L. Robbin Martin. (2006) Measurements and modeling of SiCl4 combustion in a low-pressure H2/O2 flame. Combustion and Flame 146:3, pages 407-418.
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N.M. Morgan, C.G. Wells, M.J. Goodson, M. Kraft & W. Wagner. (2006) A new numerical approach for the simulation of the growth of inorganic nanoparticles. Journal of Computational Physics 211:2, pages 638-658.
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C.G. Wells, N.M. Morgan, M. Kraft & W. Wagner. (2006) A new method for calculating the diameters of partially-sintered nanoparticles and its effect on simulated particle properties. Chemical Engineering Science 61:1, pages 158-166.
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H-R Paur, W Baumann, H Mätzing & H Seifert. (2005) Formation of nanoparticles in flames; measurement by particle mass spectrometry and numerical simulation. Nanotechnology 16:7, pages S354-S361.
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B. Giesen, H. Wiggers, A. Kowalik & P. Roth*. (2005) Formation of Si-nanoparticles in a microwave reactor: Comparison between experiments and modelling. Journal of Nanoparticle Research 7:1, pages 29-41.
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D. Vollath & D.V. Szabó. (2004) Synthesis and Properties of Nanocomposites. Advanced Engineering Materials 6:3, pages 117-127.
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S. Bailey & N.G. Glumac. (2003) Laser-induced-fluorescence detection of SnO in low-pressure particle-synthesis flames. Applied Physics B 77:4, pages 455-461.
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Karsten Wegner & Sotiris E. Pratsinis. (2004) Nozzle‐quenching process for controlled flame synthesis of titania nanoparticles. AIChE Journal 49:7, pages 1667-1675.
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M.S. Wooldridge, P.V. Torek, M.T. Donovan, D.L. Hall, T.A. Miller, T.R. Palmer & C.R. Schrock. (2002) An experimental investigation of gas-phase combustion synthesis of SiO2 nanoparticles using a multi-element diffusion flame burner. Combustion and Flame 131:1-2, pages 98-109.
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Karsten Wegner, Wendelin J Stark & Sotiris E Pratsinis. (2002) Flame-nozzle synthesis of nanoparticles with closely controlled size, morphology and crystallinity. Materials Letters 55:5, pages 318-321.
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S. Tsantilis, H.K. Kammler & S.E. Pratsinis. (2002) Population balance modeling of flame synthesis of titania nanoparticles. Chemical Engineering Science 57:12, pages 2139-2156.
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Hendrik K Kammler, Sotiris E Pratsinis, Philip W MorrisonJrJr & Bernd Hemmerling. (2002) Flame temperature measurements during electrically assisted aerosol synthesis of nanoparticles. Combustion and Flame 128:4, pages 369-381.
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Dirk Grosschmidt, Henning Bockhorn, Mike Goodson & Markus Kraft. (2002) Two approaches to the simulation of silica particle synthesis. Proceedings of the Combustion Institute 29:1, pages 1039-1046.
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Markus WintererMarkus Winterer. 2002. Nanocrystalline Ceramics. Nanocrystalline Ceramics 233 250 .
Markus WintererMarkus Winterer. 2002. Nanocrystalline Ceramics. Nanocrystalline Ceramics 35 90 .
Markus WintererMarkus Winterer. 2002. Nanocrystalline Ceramics. Nanocrystalline Ceramics 7 33 .
S.-M. Suh, M. R. Zachariah & S. L. Girshick. (2001) Modeling particle formation during low-pressure silane oxidation: Detailed chemical kinetics and aerosol dynamics. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films 19:3, pages 940-951.
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C. Janzen & P. Roth. (2001) Formation and characteristics of Fe2O3 nano-particles in doped low pressure H2/O2/Ar flames. Combustion and Flame 125:3, pages 1150-1161.
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Nick G Glumac. (2001) Formation and consumption of SiO in powder synthesis flames. Combustion and Flame 124:4, pages 702-711.
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D. Lindackers, C. Janzen, B. Rellinghaus, E.F. Wassermann & P. Roth. (1998) Synthesis of Al2O3 and SnO2 particles by oxidation of metalorganic precursors in premixed H2/O2/Ar low pressure flames. Nanostructured Materials 10:8, pages 1247-1270.
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Sotiris E. Pratsinis. (1998) Flame aerosol synthesis of ceramic powders. Progress in Energy and Combustion Science 24:3, pages 197-219.
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D. Lindackers & P. Roth. (2010) Formation of ceramic oxide nanoparticles in low pressure flames: Experiment and computersimulation. Berichte der Bunsengesellschaft für physikalische Chemie 101:11, pages 1718-1721.
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D. Lindackers & P. Roth. (1997) Flame — Generated Al2O3 — Nanoparticles. Journal of Aerosol Science 28, pages S731-S732.
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