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Low-k SiCxNy Etch-Stop/Diffusion Barrier Films for Back-End Interconnect ApplicationsLeu, Jihperng, Tu, H.E., Chang, W.Y., Chang, C.Y., Chen, Y.C., Chen, W.C., Zhou, H.Y. 22 July 2016 (has links) (PDF)
Lower k and low-leakage silicon carbonitride (SiCxNy ) films were fabricated using single precursor by using radio-frequency (RF) plasma-enhanced chemical vapor deposition (PECVD). We explored precursors with (1) cyclic-carbon-containing structures, (2) higher C/Si ratio, (3) multiple vinyl groups, as well as (4) the incorporation of porogen for developing low-k SiCxNy films as etch-stop/diffusion barrier (ES/DB) layer for copper interconnects in this study. SiCxNy films with k values between 3.0 and 3.5 were fabricated at T≦ 200 o C, and k~4.0-4.5 at 300-400 °C. Precursors with vinyl groups yielded SiCxNy films with low leakage, excellent optical transmittance and high mechanical strength due to the formation of cross-linked Si-(CH2)n-Si linkages.
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Luminescent Silicon Carbonitride Thin Films Grown using ECR PECVD: Fabrication and CharacterizationKhatami, Zahra January 2017 (has links)
McMaster University DOCTOR OF PHILOSOPHY (2017) Hamilton, Ontario
(Engineering Physics)
TITLE: Luminescent Silicon Carbonitride Thin Films Grown
using ECR PECVD: Fabrication and Characterization
AUTHOR: Zahra Khatami , M.A.Sc. (Shahid Behehsti University)
SUPERVISOR: Professor Peter Mascher
NUMBER OF PAGES: xx, 268 / Silicon, the cornerstone semiconductor of microelectronics, has seen growing interest
as a low-cost material in photonics. Nanoscience has employed various strategies to
overcome its fundamentally inefficient visible light emission such as developing new
silicon-based nanostructures and materials. Each of the proposed materials has its
own advantages and disadvantages in attempting to reach commercialization. Silicon
carbonitride (SiCxNy) is a less-studied and multi-functional material with tunable
optical features. Despite reports on promising mechanical properties of SiCxNy thin
films, they have not yet been well explored optically. This thesis presents the first in-depth analysis of the luminescent properties of
SiCxNy thin films at a broad range of compositions and temperatures. To better understand
this ternary structure, the reported data of the two fairly well studied binary
structures was used as a reference. Therefore, three classes of silicon-based materials
were produced and explored; SiCxNy, SiNx, and SiCx. Samples were fabricated using
one of the common methods in the semiconductor industry; electron cyclotron resonance
plasma enhanced chemical vapour deposition (ECR PECVD). A multitude of
characterization techniques were utilized including; optical methods (ultraviolet-visible
spectroscopy (UVVIS), variable angle spectroscopic ellipsometry (VASE), photoluminescence
(PL)) and structural techniques (elastic recoil detection (ERD), Rutherford backscattering spectrometry (RBS), X-ray photoelectron spectroscopy (XPS), Fourier
transform infrared spectroscopy (FTIR), high-resolution transmission electron microscopy
(HR-TEM)).
In view of the exploring of emission properties of SiCxNy materials, our approach
was towards the enhancement of the visible emission by adjusting the film composition
and subsequent thermal treatment. First, a systematic study of the influence of
carbon on the optical, compositional, and structural properties of SiCxNy was carried
out. This investigation was followed by an exploration of influence of growth conditions
on the visible emission and its connection with the other film properties including
hydrogen concentration, microstructure, and composition. In addition, hydrogen
diffusion was explored and associated with two featured annealing temperatures.
The key element of this thesis is the comprehensive report on the interdependency
of the visible light emission and all optical, structural, and compositional features of
SiCxNy structures. Unlocking the potential of this ternary and less studied material
can appeal to the silicon photonics community to implement it in anti-reflection,
solar cell, and sensing applications, and in particular as a substitution of SiNx used
in existing microelectronic devices. / Thesis / Doctor of Philosophy (PhD)
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Remote plasma sputtering for silicon solar cellsKaminski, Piotr M. January 2013 (has links)
The global energy market is continuously changing due to changes in demand and fuel availability. Amongst the technologies considered as capable of fulfilling these future energy requirements, Photovoltaics (PV) are one of the most promising. Currently the majority of the PV market is fulfilled by crystalline Silicon (c-Si) solar cell technology, the so called 1st generation PV. Although c-Si technology is well established there is still a lot to be done to fully exploit its potential. The cost of the devices, and their efficiencies, must be improved to allow PV to become the energy source of the future. The surface of the c-Si device is one of the most important parts of the solar cell as the surface defines the electrical and the optical properties of the device. The surface is responsible for light reflection and charge carrier recombination. The standard surface finish is a thin film layer of silicon nitride deposited by Plasma Enhanced Chemical Vapour Deposition (PECVD). In this thesis an alternative technique of coating preparation is presented. The HiTUS sputtering tool, utilising a remote plasma source, was used to deposit the surface coating. The remote plasma source is unique for solar cells application. Sputtering is a versatile process allowing growth of different films by simply changing the target and/or the deposition atmosphere. Apart from silicon nitride, alternative materials to it were also investigated including: aluminium nitride (this was the first use of the material in solar cells) silicon carbide, and silicon carbonitride. All the materials were successfully used to prepare solar cells apart from the silicon carbide, which was not used due to too high a refractive index. Screen printed solar cells with a silicon nitride coating deposited in HiTUS were prepared with an efficiency of 15.14%. The coating was deposited without the use of silane, a hazardous precursor used in the PECVD process, and without substrate heating. The elimination of both offers potential processing advantages. By applying substrate heating it was found possible to improve the surface passivation and thus improve the spectral response of the solar cell for short wavelengths. These results show that HiTUS can deposit good quality ARC for silicon solar cells. It offers optical improvement of the ARC s properties, compared to an industrial standard, by using the DL-ARC high/low refractive index coating. This coating, unlike the silicon nitride silica stack, is applicable to encapsulated cells. The surface passivation levels obtained allowed a good blue current response.
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Low-k SiCxNy Etch-Stop/Diffusion Barrier Films for Back-End Interconnect ApplicationsLeu, Jihperng, Tu, H.E., Chang, W.Y., Chang, C.Y., Chen, Y.C., Chen, W.C., Zhou, H.Y. 22 July 2016 (has links)
Lower k and low-leakage silicon carbonitride (SiCxNy ) films were fabricated using single precursor by using radio-frequency (RF) plasma-enhanced chemical vapor deposition (PECVD). We explored precursors with (1) cyclic-carbon-containing structures, (2) higher C/Si ratio, (3) multiple vinyl groups, as well as (4) the incorporation of porogen for developing low-k SiCxNy films as etch-stop/diffusion barrier (ES/DB) layer for copper interconnects in this study. SiCxNy films with k values between 3.0 and 3.5 were fabricated at T≦ 200 o C, and k~4.0-4.5 at 300-400 °C. Precursors with vinyl groups yielded SiCxNy films with low leakage, excellent optical transmittance and high mechanical strength due to the formation of cross-linked Si-(CH2)n-Si linkages.
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Nitrogen doped carbide derived carbon aerogels by chlorine etching of a SiCN aerogelZera, E., Nickel, W., Hao, G. P., Vanzetti, L., Kaskel, Stefan, Sorarù, G. D. 24 July 2017 (has links) (PDF)
Silicon was selectively removed from a silicon carbonitride (SiCN) aerogel by hot chlorine gas treatment, leading to a N-doped carbon aerogel (N-CDC aerogel). The combined effects of pyrolysis and etching temperature were studied with regard to the change in the composition of the material after etching as well as the microstructure of the produced hierarchically porous material. Upon removal of Si from amorphous SiCN, carbon and nitrogen, which are not bonded together in the starting material, react, creating new C–N bonds. The removal of silicon also gives rise to a high amount of micropores and hence a high specific surface area, which can be beneficial for the functionality of the carbonaceous material produced. The mesoporous structure of the aerogel allows us to complete the etching at low temperature, which was found to be a crucial parameter to maintain a high amount of nitrogen in the material. The combination of a high amount of micropores and the mesopore transport system is beneficial for adsorption processes due to the combination of a high amount of adsorption sites and effective transport properties of the material. The N-CDC aerogels were characterized by nitrogen physisorption, X-ray photoelectron spectroscopy (XPS), thermogravimetry (TG/DTA), and infrared spectroscopy (DRIFT) and they were evaluated as CO2 absorbers and as electrodes for electric double-layer capacitors (EDLCs).
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Nitrogen doped carbide derived carbon aerogels by chlorine etching of a SiCN aerogelZera, E., Nickel, W., Hao, G. P., Vanzetti, L., Kaskel, Stefan, Sorarù, G. D. 24 July 2017 (has links)
Silicon was selectively removed from a silicon carbonitride (SiCN) aerogel by hot chlorine gas treatment, leading to a N-doped carbon aerogel (N-CDC aerogel). The combined effects of pyrolysis and etching temperature were studied with regard to the change in the composition of the material after etching as well as the microstructure of the produced hierarchically porous material. Upon removal of Si from amorphous SiCN, carbon and nitrogen, which are not bonded together in the starting material, react, creating new C–N bonds. The removal of silicon also gives rise to a high amount of micropores and hence a high specific surface area, which can be beneficial for the functionality of the carbonaceous material produced. The mesoporous structure of the aerogel allows us to complete the etching at low temperature, which was found to be a crucial parameter to maintain a high amount of nitrogen in the material. The combination of a high amount of micropores and the mesopore transport system is beneficial for adsorption processes due to the combination of a high amount of adsorption sites and effective transport properties of the material. The N-CDC aerogels were characterized by nitrogen physisorption, X-ray photoelectron spectroscopy (XPS), thermogravimetry (TG/DTA), and infrared spectroscopy (DRIFT) and they were evaluated as CO2 absorbers and as electrodes for electric double-layer capacitors (EDLCs).
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