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

Rueger, N. R.; Beulens, JJ; Schaepkens, M.; Doemling, M. F.; Mirza, J. M.; Standaert, T. E. F. M.; Oehrlein, G. S.

doi:10.1116/1.580655

Cited by 237 publications

(71 citation statements)

References 7 publications

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“…fairly rapid etching for one material and slow etching or deposition for another material. [20][21][22][23][24][25][26] However, the thicknesses of these steady-state surface layers can be of the order of several nm. During the time needed for these to form, significant material loss can take place.…”

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confidence: 99%

Atomic Layer Etching at the Tipping Point: An Overview

Oehrlein

Metzler

2015

ECS J. Solid State Sci. Technol.

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223

162

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The ability to achieve near-atomic precision in etching different materials when transferring lithographically defined templates is a requirement of increasing importance for nanoscale structure fabrication in the semiconductor and related industries. The use of ultra-thin gate dielectrics, ultra thin channels, and sub-20 nm film thicknesses in field effect transistors and other devices requires near-atomic scale etching control and selectivity. There is an emerging consensus that as critical dimensions approach the sub-10 nm scale, the need for an etching method corresponding to Atomic Layer Deposition (ALD), i.e. Atomic Layer Etching (ALE), has become essential, and that the more than 30-year quest to complement/replace continuous directional plasma etching (PE) methods for critical applications by a sequence of individual, self-limited surface reaction steps has reached a crucial stage. A key advantage of this approach relative to continuous PE is that it enables optimization of the individual steps with regard to reactant adsorption, self-limited etching, selectivity relative to other materials, and damage of critical surface layers. In this overview we present basic approaches to ALE of materials, discuss similarities/crucial differences relative to thermal and plasma-enhanced ALD, and then review selected results on ALE of materials aimed at pattern transfer. The overview concludes with a discussion of opportunities and challenges ahead. A requirement of increasing importance for nanoscale device fabrication is the ability to achieve atomic scale etching control and materials selectivity during pattern transfer.1-8 An etching method corresponding to Atomic Layer Deposition (ALD), i.e. Atomic Layer Etching (ALE), is expected to satisfy these needs as critical dimensions continue to shrink below the 10 nm scale.Demonstrations of self-limited dry etching methods capable of near-atomic resolution have a long history in the dry etching community and a brief review will be presented below. Key challenges for these approaches have been specialized equipment, long process times and low throughput.9,10 However, a recent demonstration using a commercial plasma etch tool 10 and activities within the dry etching community 11 provide indications that the situation has changed, and that we may have reached for ALE the Tipping Point which Gladwell defined as the "the moment of critical mass, the threshold, the boiling point" when "ideas and products and messages and behaviors spread like viruses do".12 This is due to several factors, including unprecedented demands on dry etching technology introduced by the semiconductor device evolution according to Moore's law that can be satisfied by atomic layer etching, advanced capabilities in plasma etch, and the existence of a critical level of information on plasma etch and ALD methods as applied in the semiconductor fabrication space.In this article we will provide a review of background of these approaches, and focus on issues that have to be overcome for widespread implement...

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confidence: 99%

Atomic Layer Etching at the Tipping Point: An Overview

Oehrlein

Metzler

2015

ECS J. Solid State Sci. Technol.

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223

162

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“…The thickness of the fluorocarbon layer on SiO 2 is much smaller than on Si for comparable discharge conditions [4,5]. During Si etching in CF 4 + H 2 plasma the adsorption of CF 2 radicals on the Si surface is enhanced by ion bombardment, i. e. the sticking coefficient of CF 2 radicals on the Si surface is increased in the presence of ion bombardment [6].…”

Section: Introductionmentioning

confidence: 88%

Simulation of Si and SiO₂etching in CF₄+ H₂plasma

Knizikevičius¹

2004

Lith. J. Phys.

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The reactive ion etching of silicon and silicon oxide in CF4+H2 plasma is considered by the proposed model, which includes processes of adsorption, chemical reactions, desorption, sputtering, and stochastic mixing. The etching rates are calculated as functions of concentrations of chemically active and inactive plasma components and ion bombardment parameters. The chemical composition of CF4 + H2 plasma is calculated to achieve the goal. It is found that the reaction products and CF2 radicals cover the silicon surface. CF2 radicals penetrate in the bulk and form an altered layer in the near-surface region. At high H2 content in the feed (>30%), the deposition of fluorocarbon polymer takes place. Meanwhile, the concentrations of adsorbed layer components are low during SiO2 etching in CF4 + H2 plasma.

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“…4(a)]. A higher ICP power on the other hand reduced the sidewall passivation at the bottom of the TiO 2 layer, resulting in an undercut profile 26 [see Fig. 4(b)].…”

Section: -24mentioning

confidence: 99%

TiO2 membrane high-contrast grating reflectors for vertical-cavity light-emitters in the visible wavelength regime

Hashemi

Bengtsson

Gustavsson

et al. 2015

Journal of Vacuum Science &Amp; Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phen

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In this work, the authors describe a novel route to achieve a high reflectivity, wide bandwidth feedback mirror for GaN-based vertical-cavity light emitters; using air-suspended high contrast gratings in TiO2, with SiO2 as a sacrificial layer. The TiO2 film deposition and the etching processes are developed to yield grating bars without bending, and with near-ideal rectangular cross-sections. Measured optical reflectivity spectra of the fabricated high contrast gratings show very good agreement with simulations, with a high reflectivity of >95% over a 25 nm wavelength span centered around 435 nm for the transverse-magnetic polarization.

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

Cited by 237 publications

References 7 publications

Atomic Layer Etching at the Tipping Point: An Overview

Atomic Layer Etching at the Tipping Point: An Overview

Simulation of Si and SiO₂etching in CF₄+ H₂plasma

TiO2 membrane high-contrast grating reflectors for vertical-cavity light-emitters in the visible wavelength regime

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

Cited by 237 publications

References 7 publications

Atomic Layer Etching at the Tipping Point: An Overview

Atomic Layer Etching at the Tipping Point: An Overview

Simulation of Si and SiO2etching in CF4+ H2plasma

TiO2 membrane high-contrast grating reflectors for vertical-cavity light-emitters in the visible wavelength regime

Contact Info

Product

Resources

About

Simulation of Si and SiO₂etching in CF₄+ H₂plasma