Organosilicon Polymers Deposition by PECVD and RPECVD on Micropatterned Substrates

Supiot, Philippe; Vivien, Céline; Blary, K.; Rouessac, V.

doi:10.1002/cvde.201106902

Cited by 10 publications

(4 citation statements)

References 35 publications

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“…The CH absorption band that characterizes the non-oxidized APTES molecule decreases when the duty cycle increases. Oxidation of organosilicon compound is known to follow such a trend, the increase in the duty cycle leading to higher oxidation level and to a transition from plasma polymer to inorganic material [48][49][50]. Here, the transition occurs near DC=60%, in agreement with results obtained by time-resolved emission spectroscopy.…”

Section: Evolutions In Pulse Modesupporting

confidence: 87%

Interaction of (3-Aminopropyl)triethoxysilane with Pulsed Ar–O2 Afterglow: Application to Nanoparticles Synthesis

Gueye

Gries

Noël

et al. 2016

Plasma Chem Plasma Process

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The interaction of (3-Aminopropyl)triethoxysilane (APTES) with pulsed late Ar-O 2 afterglow is characterized by the synthesis of OH, CO and CO 2 in the gas phase as main by-products. Other minor species like CH, CN and C 2 H are also produced. We suggest that OH radicals are produced in a first step by dehydrogenation of APTES after interaction with oxygen atoms. In a second step, the molecule is oxidized by any O 2 state, to form peroxides that transform into by-products, break thus the precursor CC bonds. If oxidation is limited, i.e. a low duty cycle, fragmentation of the precursor is limited and produced nanoparticles keep the backbone structure of the precursor, but contain amide groups produced from the amine groups initially available in APTES. At high duty cycle, silicon-containing fragments contain some carbon and react together and produce nanoparticles with a non-silica-like structure.

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Section: Evolutions In Pulse Modesupporting

confidence: 87%

Interaction of (3-Aminopropyl)triethoxysilane with Pulsed Ar–O2 Afterglow: Application to Nanoparticles Synthesis

Gueye

Gries

Noël

et al. 2016

Plasma Chem Plasma Process

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“…The film growth rates measured for unheated substrates, were comparable for both deposition methods. However, the films produced by P‐CVD were found to be smoother than those of RP‐CVD . This was ascribed to a higher surface mobility of film‐forming species enhanced by an intense flux of oxygen atoms to a growth surface.…”

Section: Introductionmentioning

confidence: 94%

“…Only Supiot et. al . studied the growth of the films by P‐CVD and remote nitrogen plasma CVD on c‐Si surface patterned with the trenches, using the same precursor, such as 1,1,3,3‐tetramethylsiloxane admixed with oxygen.…”

Section: Introductionmentioning

confidence: 99%

Silicon Oxycarbide Films Produced by Remote Microwave Hydrogen Plasma CVD using a Tetramethyldisiloxane Precursor: Growth Kinetics, Structure, Surface Morphology, and Properties

Wróbel

Uznański

Walkiewicz-Pietrzykowska

2015

Chemical Vapor Deposition

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Amorphous hydrogenated silicon oxycarbide (a-SiCO:H) thin films are produced by remote microwave hydrogen plasma CVD using 1,1,3,3-tetramethyldisiloxane precursor. The effect of substrate temperature (T S ) on the chemical structure and some properties of resulting a-SiCO:H films is reported. The examination performed by infrared spectroscopy revealed that the increase in T S involves the elimination of organic moieties from the film and its transformation from polymer-like to ceramiclike high-crosslink-density material. Due to their small surface roughness, high density, and good optical transparency, the aSiCO:H films seem to be useful coatings for optical and electronic devices.

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“…Products of their polymerization-polysilanes and polysiloxanes-that contain Si-Si or Si-O-Si fragments possess a number of practically attractive chemical and physical properties [1][2][3][4][5]. Volatile organosilicon compounds are also famous as CVD (chemical vapor deposition) precursors for the production of silicon-containing films and ceramics [6][7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Thermal properties of some organosilicon precursors for chemical vapor deposition

Ermakova

Сысоев

Nikolaev

et al. 2016

J Therm Anal Calorim

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Five volatile organosilicon compounds: trimethyl (phenyl)silane Me 3 SiC 6 H 5 (I), trimethyl(cyclohexyl)silane Me 3 SiC 6 H 11 (II), trimethyl(phenoxy)silane Me 3 SiOC 6 H 5 (III), trimethyl(cyclohexyloxy)silane Me 3 SiOC 6 H 11 (IV), and trimethyl(allyloxy)silane Me 3 SiOC 3 H 5 (V) were synthesized, purified, and identified. Data of IR spectroscopy; gas-liquid chromatography; and 1 H NMR, 13 C NMR, 29 Si NMR analyses were used to identify and confirm the high purity of the compounds (more than 99.6 %). The thermal stability of the compounds was investigated by DTA-TG. The quantitative data on temperature dependences of the saturated vapor pressure of the compounds were obtained by static tensimetry method with glass membrane null manometer. The volatilities of compounds Me 3 SiOC 6 H 5 , Me 3 SiC 6 H 5 , Me 3 SiC 6 H 11 , Me 3 SiOC 6 H 11 were shown to be close due to the presence of large-size phenyl/cyclohexyl group. The replacement of phenyl/cyclohexyl group by allyl substituent in the molecule led to significant increase in volatility for Me 3 SiOC 3 H 5 in comparison with compounds mentioned before. The vapor pressure of all of the compounds is enough to use them as precursors in CVD processes without additional heating. The thermodynamic parameters (enthalpies and entropies) of vaporization processes for four compounds II-V were determined for the first time.

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Organosilicon Polymers Deposition by PECVD and RPECVD on Micropatterned Substrates

Cited by 10 publications

References 35 publications

Interaction of (3-Aminopropyl)triethoxysilane with Pulsed Ar–O2 Afterglow: Application to Nanoparticles Synthesis

Interaction of (3-Aminopropyl)triethoxysilane with Pulsed Ar–O2 Afterglow: Application to Nanoparticles Synthesis

Silicon Oxycarbide Films Produced by Remote Microwave Hydrogen Plasma CVD using a Tetramethyldisiloxane Precursor: Growth Kinetics, Structure, Surface Morphology, and Properties

Thermal properties of some organosilicon precursors for chemical vapor deposition

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