M. Schaepkens scite author profile

Articles you may be interested inDegradation mechanism of Schottky diodes on inductively coupled plasma-etched n-type 4H-SiCThe mechanisms underlying selective etching of a SiO 2 layer over a Si or Si 3 N 4 underlayer, a process of vital importance to modern integrated circuit fabrication technology, has been studied. Selective etching of SiO 2 -to-Si 3 N 4 in various inductively coupled fluorocarbon plasmas (CHF 3 , C 2 F 6 /C 3 F 6 , and C 3 F 6 /H 2 ) was performed, and the results compared to selective SiO 2 -to-Si etching. A fluorocarbon film is present on the surfaces of all investigated substrate materials during steady state etching conditions. A general trend is that the substrate etch rate is inversely proportional to the thickness of this fluorocarbon film. Oxide substrates are covered with a thin fluorocarbon film ͑Ͻ1.5 nm͒ during steady-state etching and at sufficiently high self-bias voltages, the oxide etch rates are found to be roughly independent of the feedgas chemistry. The fluorocarbon film thicknesses on silicon, on the other hand, are strongly dependent on the feedgas chemistry and range from ϳ2 to ϳ7 nm in the investigated process regime. The fluorocarbon film thickness on nitride is found to be intermediate between the oxide and silicon cases. The fluorocarbon film thicknesses on nitride range from ϳ1 to ϳ4 nm and the etch rates appear to be dependent on the feedgas chemistry only for specific conditions. The differences in etching behavior of SiO 2 , Si 3 N 4 , and Si are suggested to be related to a substrate-specific ability to consume carbon during etching reactions. Carbon consumption affects the balance between fluorocarbon deposition and fluorocarbon etching, which controls the fluorocarbon steady-state thickness and ultimately the substrate etching.

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High density fluorocarbon etching of silicon in an inductively coupled plasma: Mechanism of etching through a thick steady state fluorocarbon layer

Standaert

Schaepkens

Rueger

et al. 1998

235

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Document VersionPublisher's PDF, also known as Version of Record (includes final page, issue and volume numbers)Please check the document version of this publication:• A submitted manuscript is the author's version of the article upon submission and before peer-review. There can be important differences between the submitted version and the official published version of record. People interested in the research are advised to contact the author for the final version of the publication, or visit the DOI to the publisher's website.• The final author version and the galley proof are versions of the publication after peer review.• The final published version features the final layout of the paper including the volume, issue and page numbers. Link to publication General rightsCopyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights.• Users may download and print one copy of any publication from the public portal for the purpose of private study or research.• You may not further distribute the material or use it for any profit-making activity or commercial gain • You may freely distribute the URL identifying the publication in the public portal ? Take down policyIf you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. For various fluorocarbon processing chemistries in an inductively coupled plasma reactor, we have observed relatively thick ͑2-7 nm͒ fluorocarbon layers that exist on the surface during steady state etching of silicon. In steady state, the etch rate and the surface modifications of silicon do not change as a function of time. The surface modifications were characterized by in situ ellipsometry and x-ray photoelectron spectroscopy. The contribution of direct ion impact on the silicon substrate to the etching mechanism is reduced with increasing fluorocarbon layer thickness. Therefore, we consider that the silicon etch rate is controlled by a neutral etchant flux through the layer. Our experimental data show, however, that ions play an import role in the transport of silicon etching precursors through the layer. A model is developed that describes the etch kinetics through a fluorocarbon layer based on a fluorine diffusion transport mechanism. The model is consistent with the data when one or two of the following roles of the ions on the etching process are assumed. The first role is an enhancement in the diffusivity of fluorine atoms through the fluorocarbon layer and an enhancement in the reaction probability of fluorine in the fluorocarbon layer. In this case the fluorine is assumed to originate from the gas phase. The second role includes ion fragmentation and dissociation of the fluorocarbon surface molecules.

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Role of steady state fluorocarbon films in the etching of silicon dioxide using CHF3 in an inductively coupled plasma reactor

et al. 1997

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It has been found that in the etching of SiO2 using CHF3 in an inductively coupled plasma reactor of the planarized coil design, a thin steady state fluorocarbon film can play an important role in determining the rate of etching. This etching is encountered as the amount of bias power used in the SiO2 etching process is increased, and a transition from fluorocarbon film growth on the SiO2 to an oxide etching rate which is consistent with reactive sputtering theory is made. The observed presence of an intermediate region where etching occurs, although a steady state fluorocarbon film suppresses the etch rate from that expected for a reactive sputtering process, has been referred to as the fluorocarbon suppression regime. This work demonstrates the role of the steady state fluorocarbon film present on silicon dioxide during etching within the fluorocarbon suppression regime. X-ray photoelectron spectroscopy studies of the surfaces of partially etched SiO2 have shown a thinning of this film with increasing rf bias power, as well as a decrease in the fluorine content of the surface film as a function of increasing rf bias power. We have found that slight variations in the film thickness, on the order of 1 nm, can result in large variations, approximately 400 nm/min, in the silicon dioxide etch rate. The presence of the film within the suppression regime appears to be due to the overwhelming polymerization ability of high density plasmas, coupled with the inability of the oxide to react sufficiently with the total fluorocarbon particle flux in order to completely remove this film. For this reason these types of reactors exhibit a regime where oxide etching occurs in the presence of a surface film. The film appears to be directly responsible for the observed suppression of the oxide etch rate from that expected for a reactive sputtering process by dissipating the bombarding ion energy, and thereby suppressing the energy flux arriving at the oxide surface.

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A Review of SiO[sub 2] Etching Studies in Inductively Coupled Fluorocarbon Plasmas

Schaepkens

Oehrlein

2001

J. Electrochem. Soc.

104

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A comprehensive overview of results from mechanistic studies on plasma-surface interactions in inductively coupled fluorocarbon plasmas, which are currently widely used for the SiO 2 etching process in semiconductor device manufacturing industry, is presented. The plasma-surface interactions that are covered in this overview range from interactions at the plasma reactor wall and coupling window, which affect the plasma gas phase, to interactions at the substrate level, which determine the etching of both blanket surfaces and microscopic features. In particular, the effects of reactor wall temperature and parasitic capacitive coupling on the SiO 2 etching process are addressed. Further, the mechanism of selective SiO 2 to Si and Si 3 N 4 etching on blanket and inclined surfaces is discussed. Finally, it is shown how the SiO 2 etch process in high aspect ratio microstructures differs from the etch process on blanket surfaces.

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Transparent hybrid inorganic/organic barrier coatings for plastic organic light-emitting diode substrates

Kim

Yan

Erlat

et al. 2005

Journal of Vacuum Science & Technology A: Vacuum, Surfaces,

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M. Schaepkens

Study of the SiO2-to-Si3N4 etch selectivity mechanism in inductively coupled fluorocarbon plasmas and a comparison with the SiO2-to-Si mechanism

High density fluorocarbon etching of silicon in an inductively coupled plasma: Mechanism of etching through a thick steady state fluorocarbon layer

Role of steady state fluorocarbon films in the etching of silicon dioxide using CHF3 in an inductively coupled plasma reactor

A Review of SiO[sub 2] Etching Studies in Inductively Coupled Fluorocarbon Plasmas

Transparent hybrid inorganic/organic barrier coatings for plastic organic light-emitting diode substrates

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