Co-deposition of Silica, Alumina, and Aluminosilicates from Mixtures of CH3SiCl3, AlCl3, CO2, and H2. Thermodynamic Analysis and Experimental Kinetics Investigation

Nitodas, Stephanos F.; Sotirchos, Stratis V.

doi:10.1002/(sici)1521-3862(199910)5:5<219::aid-cvde219>3.0.co;2-u

Cited by 14 publications

(29 citation statements)

References 24 publications

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“…In a previous study, 22 we investigated the chemical vapor codeposition of SiO 2 , Al 2 O 3 , and aluminosilicates from mixtures of CH 3 SiCl 3 (methyltrichlorosilane, MTS), AlCl 3 , CO 2 , and H 2 . MTS was used as silicon source because preliminary experiments showed that the rates of deposition of silica and alumina from H 2 -CO 2 mixtures containing MTS and AlCl 3 , respectively, were of comparable magnitude for similar chloride concentrations, whereas mixtures of SiCl 4 , CO 2 , and H 2 gave much lower rates of deposition of silica.…”

mentioning

confidence: 99%

Chemical Vapor Deposition of Aluminosilicates from Mixtures of SiCl[sub 4], AlCl[sub 3], CO[sub 2], and H[sub 2]

Nitodas

Sotirchos

2000

J. Electrochem. Soc.

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A comprehensive study of the chemical vapor codeposition of silica, alumina, and aluminosilicates from SiCl 4 -AlCl 3 -H 2 -CO 2 mixtures is presented. A hot-wall reactor, coupled to an electronic microbalance, is used to investigate the dependence of the deposition rate on temperature, pressure, composition, and total flow rate over a broad range of operating conditions. The experimental observations are discussed in the context of the results obtained in independent deposition experiments of silica and alumina from mixtures of SiCl 4 -H 2 -CO 2 and AlCl 3 -H 2 -CO 2 , respectively, in the same apparatus. The results show that the deposition of silica proceeds at very low rates that are by more than an order of magnitude lower than those of alumina deposition at the same temperature, pressure, total flow rate, and carbon dioxide and chloride mole fractions in the feed. When both chlorides (SiCl 4 and AlCl 3 ) are fed to the reactor, that is, in the codeposition process, the rate of SiO 2 deposition is much higher than that seen in the single species deposition experiments, while the opposite behavior is observed for the rate of deposition of Al 2 O 3 . The results of deposition experiments conducted on refractory wires, in order to obtain information on the effect of the substrate position in the reactor, show that manipulation of residence time offers a way to control the composition of the codeposited films in alumina and silica. The experimental results are compared with those obtained in a past study using methyltrichlorosilane as silicon source.

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confidence: 99%

Chemical Vapor Deposition of Aluminosilicates from Mixtures of SiCl[sub 4], AlCl[sub 3], CO[sub 2], and H[sub 2]

Nitodas

Sotirchos

2000

J. Electrochem. Soc.

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“…Here it is to be considered that in a typical MCVD system, residence time at hot zone is about 0.1 second which is sufficient enough for 100% conversion of SiCl 4 to SiO 2 at temperature above 1500°C. Moreover, co-deposition of silica and alumina lowers the conversion efficiency of AlCl 3 further as reported by Nitodas et al 28 31,32 Moreover, all the aluminosilicate phases convert to mullite and cristobalite in the temperature range of 1335-1625°C. 33 So, in this study possible crystal phases that can be present are a-Al 2 O 3 , cristobalite, and mullite.…”

Section: Methodsmentioning

confidence: 58%

“…Here it is to be considered that in a typical MCVD system, residence time at hot zone is about 0.1 second which is sufficient enough for 100% conversion of SiCl 4 to SiO 2 at temperature above 1500°C. Moreover, co‐deposition of silica and alumina lowers the conversion efficiency of AlCl 3 further as reported by Nitodas et al . Around 1100°C, conversion of AlCl 3 to Al 2 O 3 merely starts, whereas SiCl 4 almost completely converts to SiO 2 at this point.…”

Section: Resultsmentioning

confidence: 99%

Synthesis and characterization of rare earth‐doped silica nanoparticles for optimizing vapor phase doping technique

Saha

Sen

2017

Int J of Appl Glass Sci

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The synthesis of rare earth‐doped aluminosilicate soot particles through vapor phase doping technique has been systematically investigated to achieve better control of rare earth homogeneity in silica glass. The experiments were designed to establish the correlation of process conditions with the physicochemical properties of the formed soot particles. Attained results depict that the characteristics of soot particles are much dependent on vapor phase compositions as well as the deposition temperature. Doping of alumina/rare earth oxide into silica matrix lowers the viscosity of the glass material at a level where size of soot particles becomes independent of deposition temperature. But dopant concentration in the formed soot samples moderately depends on the main burner temperature and by altering it appropriately one can eliminate soot layer sintering step. The paper also reports on the optimum conditions which are necessary to produce rare earth‐doped preforms of better homogeneity and thus, assist in achieving greater control over the process technology of vapor phase doping. As per the authors’ knowledge, this investigation presents completely new findings which have not been reported by any other research group earlier.

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“…The increase resulted in the formation of a very Al 2 O 3rich mullite and has been described by other authors. 10,11 (…”

Section: (1) Effect Of H 2 :Co 2 Feed Rate On Coating Composition Andmentioning

confidence: 99%

“…Nitodas and Sotirchos 10,11 report thermodynamic analysis and kinetics data for CVD of Al 2 O 3 , SiO 2 , and Al 2 O 3 -SiO 2 for CH 3 SiCl 3 (g), AlCl 3 (g), CO 2 (g), and H 2 (g) as the reactants. Their observation of suppressed Al 2 O 3 deposition during Al 2 O 3 -SiO 2 codeposition as the amount of CO 2 (g) increases is consistent with their thermodynamic calculations, which show a decrease in the concentration of aluminum-containing gaseous species as the amount of CO 2 (g) increases.…”

Section: Introductionmentioning

confidence: 99%

Optimization of Chemical Vapor Deposition Parameters for Fabrication of Oxidation‐Resistant Mullite Coatings on Silicon Nitride

Zemskova

Jones

Cooley

et al. 2004

Journal of the American Ceramic Society

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Fabrication of mullite (3Al2O3·2SiO2) coatings by chemical vapor deposition (CVD) using AlCl3–SiCl4–H2–CO2 gas mixtures was studied. The resultant CVD mullite coating microstructures were sensitive to gas‐phase composition and deposition temperature. Chemical thermodynamic calculations performed on the AlCl3–SiCl4–H2–CO2 system were used to predict an equilibrium CVD phase diagram. Results from the thermodynamic analysis, process optimization, and effects of various process parameters on coating morphology are discussed. Dense, adherent crystalline CVD mullite coatings ∼2 μm thick were successfully grown on Si3N4 substrates at 1000°C and 10.7 kPa total pressure. The resultant coatings were 001 textured and contained well‐faceted grains ∼0.3–0.5 μm in size.

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Co-deposition of Silica, Alumina, and Aluminosilicates from Mixtures of CH3SiCl3, AlCl3, CO2, and H2. Thermodynamic Analysis and Experimental Kinetics Investigation

Cited by 14 publications

References 24 publications

Chemical Vapor Deposition of Aluminosilicates from Mixtures of SiCl[sub 4], AlCl[sub 3], CO[sub 2], and H[sub 2]

Chemical Vapor Deposition of Aluminosilicates from Mixtures of SiCl[sub 4], AlCl[sub 3], CO[sub 2], and H[sub 2]

Synthesis and characterization of rare earth‐doped silica nanoparticles for optimizing vapor phase doping technique

Optimization of Chemical Vapor Deposition Parameters for Fabrication of Oxidation‐Resistant Mullite Coatings on Silicon Nitride

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