Detailed Kinetic Modeling of Silicon Nanoparticle Formation Chemistry via Automated Mechanism Generation

Wong, Hsi‐Wu; Li, Xuegeng; Swihart, Mark T.; Broadbelt, Linda J.

doi:10.1021/jp049591w

Cited by 42 publications

(73 citation statements)

References 34 publications

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“…Our observation is in line with results by Wong et al [27], who have modelled silicon nanoparticle formation via automated mechanism generation. At a simulated reactor temperature 750°C and an initial concentration of 10% SiH 4 in H 2 , these authors report cyclopentasilane to be the most abundant pentasilane species.…”

Section: Application To Silane Reactor Monitoringsupporting

confidence: 93%

“…[13][14][15][16][17][18][19][20] and by modelling [see e.g. 13,16,[20][21][22][23][24][25][26][27], have been conducted to broaden the understanding of the monosilane pyrolysis. It is commonly accepted that the pyrolysis occurs through a series of chemical reactions, including SiASi bond formation and hydrogen elimination, producing silanes with increasing number of Si atoms [13,20,22,23,28,29].…”

Section: Pyrolysis Of Sih 4 In Solar Silicon Industrymentioning

confidence: 99%

“…Additionally, 1,2-hydrogen shifts, ring opening and ring closing lead to interconversion between different isomers within each silane family [22,23,30,31]. Many of the kinetic models of the monosilane pyrolysis process have an impressive degree of detail, some of which include hundreds of species with up to 10 Si atoms and more than one thousand chemical reactions [16,[21][22][23]27]. The experimental works in the field, on the other hand, have a much lower degree of detail.…”

Section: Pyrolysis Of Sih 4 In Solar Silicon Industrymentioning

confidence: 99%

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Identification of higher order silanes during monosilane pyrolysis using gas chromatography-mass spectrometry

Wyller

Klette

Mongstad

et al. 2018

Journal of Crystal Growth

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a b s t r a c tThere is a deficit of ways to detect higher order silane isomers during silane pyrolysis. Thus, a novel instrument utilizing gas chromatography-mass spectrometry (GC-MS) for detection of higher order silanes has been developed. The instrument enables us to separate higher order silane species using gas chromatography before they are introduced to the mass spectrometer, thereby obtaining spectra of separate isomers, rather than overlaid spectra. In this contribution we describe the details of the GC-MS system. We compare our GC-separated mass spectra of mono-, di-and trisilane to mass spectra of these species available in the literature. Further, we present mass spectra of the tetrasilane isomers n-tetrasilane (n-Si 4 H 10 ), silyltrisilane (i-Si 4 H 10 ) and cyclotetrasilane (cyclo-Si 4 H 8 ) and of the pentasilane isomers n-pentasilane (n-Si 5 H 12 ), silyltetrasilane (i-Si 5 H 12 ) disilyltrisilane (neo-Si 5 H 12 ) and cyclopentasilane (cyclo-Si 5 H 10 ). Six of these mass spectra are previously unpublished. Based on the fragmentation pattern in the tetra-and pentasilane mass spectra, we are able to acquire mass spectra of silanes with up to eight silicon atoms. Finally, we apply the novel detection technique to a silane pyrolysis reactor to track the outlet concentration of higher order silanes as function of reactor temperature. We believe that the detection technique that we present here may open the door for validation of monosilane pyrolysis models, and thus constitute a roadmap for future research in this field.

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Section: Application To Silane Reactor Monitoringsupporting

confidence: 93%

Section: Pyrolysis Of Sih 4 In Solar Silicon Industrymentioning

confidence: 99%

Section: Pyrolysis Of Sih 4 In Solar Silicon Industrymentioning

confidence: 99%

See 1 more Smart Citation

Identification of higher order silanes during monosilane pyrolysis using gas chromatography-mass spectrometry

Wyller

Klette

Mongstad

et al. 2018

Journal of Crystal Growth

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“…Numerous studies of silane decomposition kinetics have been reported (Becerra and Walsh 1992;Ho et al 1994;Moffat et al 1992a, b;Purnell and Walsh 1984;Wong et al 2004). As in Dang and Swihart (2008), this work used an extensive chemical kinetic mechanism for silicon hydride cluster formation during silane pyrolysis (Swihart and Girshick 1999).…”

Section: Cfd Simulationmentioning

confidence: 98%

Computational Modeling of Silicon Nanoparticle Synthesis: II. A Two-Dimensional Bivariate Model for Silicon Nanoparticle Synthesis in a Laser-Driven Reactor Including Finite-Rate Coalescence

Dang

Swihart

2009

Aerosol Science and Technology

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In this work, a two-dimensional model was developed for silicon nanoparticle synthesis by silane thermal decomposition in a sixway cross laser-driven aerosol reactor. This two-dimensional model incorporates fluid dynamics, laser heating, gas phase and surface phase chemical reactions, and aerosol dynamics, with particle transport and evolution by convection, diffusion, thermophoresis, nucleation, surface growth, coagulation, and coalescence processes. Because of the complexity of the problem at hand, the simulation was carried out via several sub-models. First, the chemically reacting flow inside the reactor was simulated in three dimensions in full geometric detail, but with no aerosol dynamics and with highly simplified chemistry. Second, the reaction zone was simulated using an axisymmetric two-dimensional CFD model, whose boundary conditions were obtained from the first step. Last, a twodimensional aerosol dynamics model was used to study the silicon nanoparticle formation using more complete silane decomposition chemistry, together with the temperature and velocities extracted from the reaction zone CFD simulation. A bivariate model was used to describe the evolution of particle size and morphology. The aggregates were modeled by a moment method, assuming a lognormal distribution in particle volume. This was augmented by a single balance equation for primary particles that assumed locally equal number of primary particles per aggregate and fractal dimension. The model predicted the position and size at which the primary particle size is frozen in, and showed that increasing the peak temperature was a more effective means of improving particle yield than increasing silane concentration or flowrate.

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“…-coke formation (Moustafa and Froment, 2003;QuintanaSolórzano et al, 2005), -biomass conversion (Rangarajan et al, 2010), -oxidative coupling of methane (Simon et al, 2007), -silicon hydride clustering (Wong et al, 2004), -hydrocarboxylation , -carbonylation (Bruk et al, 1998), -organic synthesis (Fontain and Reitsam, 1991), -biological processes (Valdes-Perez, 1992b;Klein et al, 2002;Faeder et al, 2003Faeder et al, , 2005Li et al, 2004;Hatzimanikatis et al, 2004Hatzimanikatis et al, , 2005Blinov et al, 2005a, b;Mayeno et al, 2005;Henry et al, 2007Henry et al, , 2010Hill et al, 2008;Finley et al, 2009), -and many more.…”

Section: Simulation Of Large Complex Reaction Network 421 Network mentioning

confidence: 99%

A Review of Kinetic Modeling Methodologies for Complex Processes

Oliveira

Hudebine

Denis

et al. 2016

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

125

113

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-In this paper, kinetic modeling techniques for complex chemical processes are reviewed. After a brief historical overview of chemical kinetics, an overview is given of the theoretical background of kinetic modeling of elementary steps and of multistep reactions. Classic lumping techniques are introduced and analyzed. Two examples of lumped kinetic models (atmospheric gasoil hydrotreating and residue hydroprocessing) developed at IFP Energies nouvelles (IFPEN) are presented. The largest part of this review describes advanced kinetic modeling strategies, in which the molecular detail is retained, i.e. the reactions are represented between molecules or even subdivided into elementary steps. To be able to retain this molecular level throughout the kinetic model and the reactor simulations, several hurdles have to be cleared first: (i) the feedstock needs to be described in terms of molecules, (ii) large reaction networks need to be automatically generated, and (iii) a large number of rate equations with their rate parameters need to be derived. For these three obstacles, molecular reconstruction techniques, deterministic or stochastic network generation programs, and single-event micro-kinetics and/or linear free energy relationships have been applied at IFPEN, as illustrated by several examples of kinetic models for industrial refining processes.Résumé -Une revue de méthodes de modélisation cinétique pour des procédés complexesDans cet article, les techniques de modélisation cinétique des processus chimiques complexes sont examinées. Après un bref aperçu historique de la cinétique chimique, un aperçu des bases théoriques de la modélisation cinétique d'étapes élémentaires et de réactions globales est présenté. Les techniques classiques de regroupement (lumping) sont ensuite présentées et analysées. Deux exemples de modèles cinétiques regroupés (pour l'hydrotraitement de gazole atmosphérique et pour l'hydrotraitement de résidus) développés à IFP Energies nouvelles (IFPEN) sont présentés. La plus grande partie de cette revue décrit des stratégies avancées de modélisation cinétique, dans lesquelles le détail moléculaire est retenu : les réactions entre les molécules sont représentées ou même subdivisées en étapes élémentaires. Pour être en mesure de conserver ce niveau moléculaire à la fois dans le modèle cinétique et dans les simulations de réacteurs, plusieurs obstacles doivent d'abord être éliminés : (i) la charge doit être décrite en termes de molécules, (ii) les grands réseaux réactionnels doivent être générés automatiquement et (iii) un grand nombre d'équations de vitesse avec leurs paramètres de vitesse doit être dérivé. Pour ces trois obstacles, des techniques de reconstruction moléculaire, des programmes de génération de réseaux déterministes ou stochastiques, et des modèles microcinétiques basés sur des événements constitutifs (single events) et/ou des

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Detailed Kinetic Modeling of Silicon Nanoparticle Formation Chemistry via Automated Mechanism Generation

Cited by 42 publications

References 34 publications

Identification of higher order silanes during monosilane pyrolysis using gas chromatography-mass spectrometry

Identification of higher order silanes during monosilane pyrolysis using gas chromatography-mass spectrometry

Computational Modeling of Silicon Nanoparticle Synthesis: II. A Two-Dimensional Bivariate Model for Silicon Nanoparticle Synthesis in a Laser-Driven Reactor Including Finite-Rate Coalescence

A Review of Kinetic Modeling Methodologies for Complex Processes

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