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Silicon nitride

About: Silicon nitride is a research topic. Over the lifetime, 32678 publications have been published within this topic receiving 413599 citations. The topic is also known as: N₄Si₃.


Papers
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Journal ArticleDOI
TL;DR: The injection level dependence of the effective surface recombination velocity (Seff) for the interface between crystalline silicon and stoichiometric silicon nitride, prepared by high-frequency direct plasma enhanced chemical vapour deposition (PECVD), has been comprehensively studied in this article.
Abstract: The injection level dependence of the effective surface recombination velocity (Seff) for the interface between crystalline silicon and stoichiometric silicon nitride, prepared by high-frequency direct plasma enhanced chemical vapour deposition (PECVD), has been comprehensively studied. A wide variety of substrate resistivities for both n-type and p-type dopants have been investigated for minority carrier injection levels (Δn) between 1012 and 1017 cm−3. Effective lifetimes of 10 ms have been measured for high resistivity n-type and p-type silicon, the highest ever measured for silicon nitride passivated wafers, resulting in Seff values of 1 cm s−1 being unambiguously determined. The Seff(Δn) dependence is shown to be constant for n-type silicon under low injection conditions, while for p-type silicon, there is a clear minimum to Seff for injection levels close to the doping density. Further, the Seff(Δn) dependence for these stoichiometric silicon nitride films appears to be weaker than that for other high-quality, silicon-rich silicon nitride films prepared by remote PECVD.

134 citations

Patent
Jie Liu1, Xikun Wang1, Seung Park1, Mikhail Korolik1, Anchuan Wang1, Nitin K. Ingle1 
20 Dec 2013
TL;DR: In this paper, a remote plasma etch using plasma effluents formed from a fluorine-containing precursor in combination with ammonia (NH 3 ) is described, where the plasmas react with exposed surfaces and selectively remove tungsten oxide while very slowly removing other exposed materials.
Abstract: Methods of selectively etching tungsten oxide relative to tungsten, silicon oxide, silicon nitride and/or titanium nitride are described. The methods include a remote plasma etch using plasma effluents formed from a fluorine-containing precursor in combination with ammonia (NH 3 ). Plasma effluents from the remote plasma are flowed into a substrate processing region where the plasma effluents react with the tungsten oxide. The plasmas effluents react with exposed surfaces and selectively remove tungsten oxide while very slowly removing other exposed materials. Increasing a flow of ammonia during the process removes a typical skin of tungsten oxide having higher oxidation coordination number first and then selectively etching lower oxidation tungsten oxide. In some embodiments, the tungsten oxide etch selectivity results partly from the presence of an ion suppression element positioned between the remote plasma and the substrate processing region.

133 citations

Patent
16 Dec 1993
TL;DR: In this paper, a hydrogen halide plasma is created within an etch chamber and the negative charge at the bottom of the chamber attracts the positively charged plasma, thereby etching the substrate in the downward direction.
Abstract: Silicon dioxide on a substrate is directionally etched using a hydrogen halide plasma which is created within an etch chamber. The method selectively etches silicon dioxide relative to polysilicon and silicon nitride. A substrate and the combination of NH 3 and NF 3 gases or the combination of CF 4 and O 2 gases mixed with H 2 and N 2 gases are located within an etch chamber. An electrical field is created within the etch chamber causing the gas mixture to form a plasma. The negative charge at the bottom of the chamber attracts the positively charged plasma, thereby etching the substrate in the downward direction. The result is an anisotropic product. The method is also shown to be effective in non-selectively etching thermal and deposited oxides, resulting in a similar etch rate for the different types of oxides.

133 citations

Journal ArticleDOI
TL;DR: This paper focuses on the integration, process, and reliability requirements for dielectric films used for isolation, passivation, barrier, and antireflectivecoating applications in ultralargescale integrated (ULSI) semiconductor circuits.
Abstract: Plasma-assisted deposition of thin films is widely used in microelectronic circuit manufacturing. Materials deposited include conductors such as tungsten, copper, aluminum, transition-metal silicides, and refractory metals, semiconductors such as gallium arsenide, epitaxial and polycrystalline silicon, and dielectrics such as silicon oxide, silicon nitride, and silicon oxynitride. This paper reviews plasma-assisted chemical vapor deposition (CVD) applications and techniques for dielectric thin films. In particular, we focus on the integration, process, and reliability requirements for dielectric films used for isolation, passivation, barrier, and antireflectivecoating applications in ultralargescale integrated (ULSI) semiconductor circuits. In addition, manufacturing issues and considerations for further work are discussed.

133 citations


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Performance
Metrics
No. of papers in the topic in previous years
YearPapers
2023245
2022529
2021421
2020686
2019994
2018911