Hochmolekulare Perchlorsiloxane

Binnewies, Michael; Jerzembeck, Marion; Wilkening, Andreas

doi:10.1002/zaac.19976231209

Cited by 9 publications

(13 citation statements)

References 19 publications

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“…[17] Another impressive example has recently been published; it is concerned with chemical vapor deposition of silicon dioxide from silicon tetrachloride and oxygen. [18] In this study chlorine-substituted, soluble polysiloxanes with a molecular mass of several thousand have been detected. The problem of complex gas-phase reactions in relation to the overall deposition process has been treated in several chapters of reference.…”

Section: Resultsmentioning

confidence: 97%

CVD in Hot Wall Reactors—The Interaction Between Homogeneous Gas-Phase and Heterogeneous Surface Reactions

Hüttinger¹

1998

Chem. Vap. Deposition

129

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The paper is concerned with chemical vapor deposition in hot wall reactors and in particular with the interaction of homogeneous gas-phase and heterogeneous surface reactions. Based on model considerations it is shown that this interaction has a tremendous influence on the deposition chemistry and kinetics in all cases in which the precursor gas undergoes complex gasphase reactions. The decisive parameter determining the interaction is given by the ratio of free volume of the deposition space and size of the surface area of the substrate; it is termed the "third parameter" of chemical vapor deposition. Predictions from the model are experimentally confirmed using results on chemical vapor deposition of pyrolytic carbon from methane. The importance of this "third parameter" of chemical vapor deposition in investigations of kinetics and for technical processes of chemical vapor deposition and infiltration is discussed in the conclusion.

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Section: Resultsmentioning

confidence: 97%

CVD in Hot Wall Reactors—The Interaction Between Homogeneous Gas-Phase and Heterogeneous Surface Reactions

Hüttinger¹

1998

Chem. Vap. Deposition

129

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“…The reaction of SiCl 4 with O 2 is of great technological importance for the chemical vapor deposition (CVD) of solid SiO 2 films used in the microelectronics industry and synthesis of the ceramic powders. − The basic reaction occurs when the mixture of O 2 with SiCl 4 , in a tube of about 30 cm length, is heated above 1000 °C. , However, in the temperature range of 800−1000 °C, the resulting product consists of a multitude of chlorosiloxanes of the general formula Si x O y Cl z . , These chlorosiloxanes have a variety of shapes and sizes ranging from chains and rings to oligocyclic and polycyclic shapes. A large number of chlorosiloxanes were identified by mass spectrometry. − These chlorosiloxanes are intermediate compounds formed in the course of the reaction because of the partial replacement of Cl atoms in SiCl 4 by oxygen atoms.…”

Section: Introductionmentioning

confidence: 99%

“…5,6 However, in the temperature range of 800-1000 °C, the resulting product consists of a multitude of chlorosiloxanes of the general formula Si x O y Cl z . 6,7 These chlorosiloxanes have a variety of shapes and sizes ranging from chains and rings to oligocyclic and polycyclic shapes. A large number of chlorosiloxanes were identified by mass spectrometry.…”

Section: Introductionmentioning

confidence: 99%

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Reaction Mechanism of Chlorosiloxane Ring Formation from SiCl₄ and O₂

2002

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The formation of the chlorosiloxane ring (Cl 2 SiO) 2 from the reaction of SiCl 4 with O 2 has been studied using density functional theory (DFT). Geometries of reactants, intermediates, transition states, and products were fully optimized, and the relative energies of the stationary points and all of the transition states were calculated on the B3LYP/6-311G* level. The initial reaction of O 2 with SiCl 4 starts on the triplet surface with the insertion of O 2 in SiCl 4 . This will loosen one Cl atom, and a barrier of 56.6 kcal/mol must be overcome. In the next step Cl 2 is eliminated and the cyclic-Cl 2 SiO 2 is formed. The latter reacts with SiCl 4 , which involves a barrier of 76.0 kcal/mol. This process leads to the formation of a low-lying intermediate Cl 2 SiO(OCl)SiCl 3 . The intermediate proceeds under elimination of Cl 2 to the product (Cl 2 SiO) 2 ring over a barrier of 71.3 kcal/ mol. This study also shows that the formation of the Cl 3 SiO radical is found to be energetically more favorable than that of Cl 2 SiO. This can lead to the growth of larger chlorosiloxanes.

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“…The importance of siloxanes in chemical vapor deposition (CVD) processes has been repeatedly discussed. , In the combustion of SiCl 4 in O 2 , which leads to silicon dioxide, hundreds of intermediates of chlorosiloxanes have been detected. − Such cluster compounds can be considered as connecting links between molecules and solids. Among the siloxanes, the silsesquioxanes of composition Si n O 3 n /2 R n (R = Cl, H, or other substituents) are most interesting.…”

Section: Introductionmentioning

confidence: 99%

Nonclassical Pathways for Silsesquioxane Growth

and

Gloriozov

2002

J. Phys. Chem. A

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The mechanism of silsesquioxane growth is studied with an insertion mechanism analogous to the one previously proposed for fullerene growth. Different from previous work, the possibility of the involvement of larger rings with (SiO)7 size in cages of hydridosilsesquioxanes Si n O3 n /2H n is investigated. Such a nonclassical pathway is calculated for the growth of Si30O45H30 via Si32O48H32 to Si34O51H34. The MSINDO method is used to determine the transition structures and intermediates. It is found that nonclassical pathways are equally preferable as classical pathways involving cages with (SiO)5 and (SiO)6 rings only.

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Hochmolekulare Perchlorsiloxane

Cited by 9 publications

References 19 publications

CVD in Hot Wall Reactors—The Interaction Between Homogeneous Gas-Phase and Heterogeneous Surface Reactions

CVD in Hot Wall Reactors—The Interaction Between Homogeneous Gas-Phase and Heterogeneous Surface Reactions

Reaction Mechanism of Chlorosiloxane Ring Formation from SiCl₄ and O₂

Nonclassical Pathways for Silsesquioxane Growth

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Hochmolekulare Perchlorsiloxane

Cited by 9 publications

References 19 publications

CVD in Hot Wall Reactors—The Interaction Between Homogeneous Gas-Phase and Heterogeneous Surface Reactions

CVD in Hot Wall Reactors—The Interaction Between Homogeneous Gas-Phase and Heterogeneous Surface Reactions

Reaction Mechanism of Chlorosiloxane Ring Formation from SiCl4 and O2

Nonclassical Pathways for Silsesquioxane Growth

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Reaction Mechanism of Chlorosiloxane Ring Formation from SiCl₄ and O₂