A Study of Trimethylsilane (3MS) and Tetramethylsilane (4MS) Based α-SiCN:H/α-SiCO:H Diffusion Barrier Films

Chen, Sheng-Wen; Wang, Yusheng; Hu, Shao-Yu; Lee, Wen−Hsi; Chi, Chieh-Cheng; Wang, Ying-Lang

doi:10.3390/ma5030377

Cited by 19 publications

(10 citation statements)

References 13 publications

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“…The ATR spectra point to a reduction in the intensity associated with the Si–N and Si–C vibrations at 890 and 820 cm –1 consequently on the SiCN surface, − which can be attributed to a reduction of the C and N content induced by the plasma, in agreement with the XPS spectra shown in Figure b–d and to O–H and Si–O groups formation after the plasma treatment followed by the atmospheric exposure.…”

Section: Discussionsupporting

confidence: 78%

Selective Ru ALD as a Catalyst for Sub-Seven-Nanometer Bottom-Up Metal Interconnects

Zyulkov

Krishtab

Gendt

et al. 2017

ACS Appl. Mater. Interfaces

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Integrating bottom-up area-selective building-blocks in microelectronics has a disruptive potential because of the unique capability of engineering new structures and architectures. Atomic layer deposition (ALD) is an enabling technology, yet understanding the surfaces and their modification is crucial to leverage area-selective ALD (AS-ALD) in this field. The understanding of general selectivity mechanisms and the compatibility of plasma surface modifications with existing materials and processes, both at research and production scale, will greatly facilitate AS-ALD integration in microelectronics. The use of self-assembled monolayers to inhibit the nucleation and growth of ALD films is still scarcely compatible with nanofabrication because of defectivity and downscaling limitations. Alternatively, in this Research Article, we demonstrate a straightforward H plasma surface modification process capable of inhibiting Ru ALD nucleation on an amorphous carbon surface while still allowing instantaneous nucleation and linear growth on Si-containing materials. Furthermore, we demonstrate how AS-ALD enables previously inaccessible routes, such as bottom-up electroless metal deposition in a dual damascene etch-damage free low-k replacement scheme. Specifically, our approach offers a general strategy for scalable ultrafine 3D nanostructures without the burden of subtractive metal patterning and high cost chemical mechanical planarization processes.

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Section: Discussionsupporting

confidence: 78%

Selective Ru ALD as a Catalyst for Sub-Seven-Nanometer Bottom-Up Metal Interconnects

Zyulkov

Krishtab

Gendt

et al. 2017

ACS Appl. Mater. Interfaces

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“…Figure 2a presents the refractive index ( n ) of a‐SiCN films deposited from DMADMS, TDMAS, TMDSN, and BDMAMS precursors as a function of substrate temperature ( T S ) and shows that n increases markedly with increasing T S reaching for BDMAMS films at T S = 350–400°C with very high values of n = 2.01–2.02. The trends observed for n curves in Figure 2a are due to thermally induced crosslinking reactions resulting in the formation of the Si−C and Si−N networks, [ 32 ] which cause densification of the film and the resulting increase of the refractive index. This is evidently proved by the relationships between the refractive index and density exemplified in Figure 2b for DMADMS and BSCDSM films.…”

Section: Optical Propertiesmentioning

confidence: 99%

“…[ 31 ] In view of these unique features, SiCN films are very promising coatings for advanced technology. For example, they may be used as wear‐resistant tribological coatings for steel surface, [ 17‐19 ] diffusion barrier coatings for copper, [ 32 ] separation membranes for a small molecule gas, [ 33 ] or components for optical interference filters with a gradient of refractive index. [ 34 ]…”

Section: Introductionmentioning

confidence: 99%

Hard silicon carbonitride thin‐film coatings by remote hydrogen plasma chemical vapor deposition using aminosilane and silazane precursors. 2: Physical, optical, and mechanical properties of deposited films

Wróbel

Uznański

2021

Plasma Processes & Polymers

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Physical, optical, and mechanical properties of silicon carbonitride (a‐SiCN) films produced by remote hydrogen plasma chemical vapor deposition (RP‐CVD) using aminosilane and disilazane precursors are examined in relation to their chemical structure. The films deposited at different temperatures (30–400°C) were characterized in terms of their density, refractive index, optical bandgap, photoluminescence, adhesion to a substrate, hardness, elastic modulus resistance to wear (predicted from the “plasticity index” values), and friction coefficient. Reasonable structural dependencies of film properties were determined using the relative integrated intensities of the infrared absorption bands from the Si−N and Si−C bonds, and the X‐ray photoelectron spectroscopy Si2p band from the Si−C bonds (controlled by substrate temperature) evaluated in the first part of this study. In view of their good mechanical properties, a‐SiCN films seem to be useful coatings for improving surface mechanics of engineering materials for advanced technology.

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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]. SiC:H and SiCN:H films are perspective as low-k dielectrics and Cu diffusion barriers.…”

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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A Study of Trimethylsilane (3MS) and Tetramethylsilane (4MS) Based α-SiCN:H/α-SiCO:H Diffusion Barrier Films

Cited by 19 publications

References 13 publications

Selective Ru ALD as a Catalyst for Sub-Seven-Nanometer Bottom-Up Metal Interconnects

Selective Ru ALD as a Catalyst for Sub-Seven-Nanometer Bottom-Up Metal Interconnects

Hard silicon carbonitride thin‐film coatings by remote hydrogen plasma chemical vapor deposition using aminosilane and silazane precursors. 2: Physical, optical, and mechanical properties of deposited films

Thermal properties of some organosilicon precursors for chemical vapor deposition

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