Reactive Plasma Jet High‐Rate Etching of SiC

Eichentopf, Inga-Maria; Böhm, G.; Meister, Johannes; Arnold, Thomas

doi:10.1002/ppap.200930503

Cited by 11 publications

(6 citation statements)

References 14 publications

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“…on/in the silicon carbide substrate. As of today, there is a fairly large variety of techniques for the processing of silicon carbide that allow, to some extent, to solve the following problem: wet etching; etching in solvents, stimulated by femtosecond laser; plasma etching; etching in plasma atmospheric discharge; plasma jet processing, and etc [15][16][17][18][19][20][21][22][23][24][25] . The choice of silicon carbide processing method is determined by the specific target, but nevertheless any of the methods must meet a number of general requirements: minimal defect formation on the surface of the etched profile, high etching rates, and high directionality of the processed window during the etching process.…”

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confidence: 99%

High-temperature etching of SiC in SF6/O2 inductively coupled plasma

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Iankevich

Speshilova

et al. 2020

Sci Rep

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In this work, we demonstrate an effective way of deep (30 µm depth), highly oriented (90° sidewall angle) structures formation with sub-nanometer surface roughness (Rms = 0.7 nm) in silicon carbide (SiC). These structures were obtained by dry etching in SF6/O2 inductively coupled plasma (ICP) at increased substrate holder temperatures. It was shown that change in the temperature of the substrate holder in the range from 100 to 300 °C leads to a sharp decrease in the root mean square roughness from 153 to 0.7 nm. Along with this, it has been established that the etching rate of SiC also depends on the temperature of the substrate holder and reaches its maximum (1.28 µm/min) at temperatures close to 150 °C. Further temperature increase to 300 °C does not lead to the etching rate rising. The comparison of the results of the thermally stimulated process and the etching with a water-cooled substrate holder (15 °C) is carried out. Plasma optical emission spectroscopy was carried out at different temperatures of the substrate holder.

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confidence: 99%

High-temperature etching of SiC in SF6/O2 inductively coupled plasma

Осипов

Iankevich

Speshilova

et al. 2020

Sci Rep

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“…One of the drawbacks of PJM is the limited choice of materials, since the material removal process is based on a purely chemical mechanism that converts the solid substrate surface to gaseous compounds. So far mostly etching processes for silicon and silicon‐based materials, such as fused silica, Si 3 N 4 , or SiC have been investigated using fluorine‐based chemistry (e.g., using CF 4 and SF 6 as precursor gases) . Extending the choice of reactive gas components opens up a whole new range of materials that can be plasma jet processed.…”

Section: Introductionmentioning

confidence: 99%

“…Optical surfaces of ultimate precision have become indispensable for a broad spectrum of applications ranging from high quality imaging optics, over custom shaped freeform optics for research applications, space applications, and synchrotron optics to extreme ultra-violet lithography for the latest generation of semiconductor devices. [1][2][3] Besides the ongoing improvement of traditional, mechanicalabrasive surface figuring methods like grinding or polishing, alternative technologies for deterministic optical manufacturing employing sub-aperture tools based on ion beams and plasma jets have been developed, circumventing limitations regarding the reachable form accuracy surfaces. Plasma Jet Machining (PJM) technology, which is addressed in this work, is capable to fabricate a wide range of complex optical surface shapes (e.g., aspheres, acylinders, toroids, freeforms) with form accuracy down to the nanometer, with the qualification of being measureable.…”

Section: Introductionmentioning

confidence: 99%

“…So far mostly etching processes for silicon and silicon-based materials, such as fused silica, Si 3 N 4 , or SiC have been investigated using fluorine-based chemistry (e.g., using CF 4 and SF 6 as precursor gases). [2,5] Extending the choice of reactive gas components opens up a whole new range of materials that can be plasma jet processed. It is well known from semiconductor processes that chlorine containing plasmas are suitable for etching metals, such as titanium or aluminum, or oxides like Al 2 O 3 .…”

Section: Introductionmentioning

confidence: 99%

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Etch Mechanism and Temperature Regimes of an Atmospheric Pressure Chlorine-Based Plasma Jet Process

Piechulla

Bauer

Boehm

et al. 2016

Plasma Process. Polym.

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Reactive atmospheric plasma jets containing halogenous compounds are employed as locally acting tools for surface figure shaping or surface modification in ultra‐precision surface machining technologies. In the current study, the interaction between an atmospheric CCl4/O2 containing plasma jet with silicon surface is investigated aiming at elucidating the chemical kinetics of surface reactions. Different process regimes are identified comprising material removal as well as polymeric and oxide layer formation, which depend on the ratio of the reactive components and substrate surface temperature. XPS and SEM measurements support the findings.

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“…Schindler et al studied the relationship between the removal rate of quartz and the substrate temperature [13] . Eichentopf et al researched the dependence of the removal rate of SiC on the gas mixtures and sample temperature [14] . Takino et al studied the effect of the gap distance between the electrode and the workpiece surface on the removal rate of synthetic silica glass [15] .…”

Section: Introductionmentioning

confidence: 99%

Atmospheric Pressure Plasma Processing of Fused Silica in Different Discharge Modes

Xin

Zhang

et al. 2015

Plasma Sci. Technol.

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One of the major advantages of utilizing atmospheric pressure plasma processing (APPP) technology to fabricate ultra-precision optics is that there is no subsurface damage during the process. In APPP, the removal footprint and removal rate are critical to the capability and efficiency of the figuring of the optical surface. In this paper, an atmospheric plasma torch, which can work in both remote mode and contact mode, is presented. The footprints and the removal rates of both modes are compared by profilometer measurements. The influences of process recipes and substrate thickness for both modes are investigated through a series of experiments. When the substrate is thinner than 12 mm, the removal rate in contact mode is higher. However, the removal rate and width of the footprint decrease dramatically as the substrate thickness increases in contact mode.

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Reactive Plasma Jet High‐Rate Etching of SiC

Cited by 11 publications

References 14 publications

High-temperature etching of SiC in SF6/O2 inductively coupled plasma

High-temperature etching of SiC in SF6/O2 inductively coupled plasma

Etch Mechanism and Temperature Regimes of an Atmospheric Pressure Chlorine-Based Plasma Jet Process

Atmospheric Pressure Plasma Processing of Fused Silica in Different Discharge Modes

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