Synthesis of Few‐Layer Graphene‐on‐Insulator Films by Controllable C<sub>4</sub>F<sub>8</sub> Plasma Etching SiC

Chen, Jin; Huang, Teng; Yang, Yan; Wu, Mingzhi; Xu, Yi–Jun; Wu, Zhaofeng; Zhuge, Lanjian; Wu, Xuemei; Ye, Chao

doi:10.1002/ppap.201400181

Cited by 8 publications

(7 citation statements)

References 33 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

Осипов

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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“…Plasma treatment of graphene surfaces has been shown to successfully modify the basal plane of graphene without the creation of harsh by-products [8] [9] [10] [11]. Plasma modi cation of graphene utilizes energetic and/or reactive radicals in the plasma to interact with the surface and can have several effects, such as breaking the C-C bonds, removing surface atoms, "cleaning" the surface, and modifying the surface chemistry [12]. The surface reactions are determined by the types of plasma species and energy, which depend on the plasma system, source gas and pressure, and excitation power.…”

Section: Introductionmentioning

confidence: 99%

Plasma Modification of Graphene Nanoplatelets Surfaces

Johnson

Wang

Fan

et al. 2023

Preprint

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Atmospheric plasma processing, which combines the efficacy of chemical processes and the safety of physical processes, has been used to modify the surface characteristic of graphite-based materials. In this work, two distinct plasma source gases, C4F8 and O2, with the addition of a rotary reactor were used. The effectiveness to modify the basal plane of intercalated graphite nanoplatelets (GnP) was investigated with various analytical techniques and the visual observation of the dispersion of these plasma-treated GnP in solvents was also reported. It is shown that this low-temperature plasma processing technique can be used to successfully modify the GnP surface without significantly changing the intrinsic structure of the GnP, which is desirable in many applications. With the C4F8 plasma treatment, the immersion characteristics in solvents can be tuned and the functional groups present on the surface can be tailored to produce desired bonding environments. This surface chemistry tunability is expected to provide the needed functionalities in creating graphene-containing composite materials.

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“…Several groups have used plasma treatments of SiC for graphene growth. [20][21][22][23][24][25] For example, Raghavan et al reported that the surface chemistry using CF 4 -and Cl 2 -based inductively coupled plasma-reactive ion etching of a SiC(0001) surface followed by thermal annealing has the potential to yield a large-area graphene film. 20 A C 4 F 8 -based fluorocarbon plasma was also used to etch a Si-face SiC surface prior to annealing in an Ar gas for nucleating and growing graphene films.…”

Section: Introductionmentioning

confidence: 99%

“…20 A C 4 F 8 -based fluorocarbon plasma was also used to etch a Si-face SiC surface prior to annealing in an Ar gas for nucleating and growing graphene films. 21,22 Tsai et al exposed a SiC surface to N 2 plasma to promote the reaction of nitrogen ions with Si, which was followed by annealing at 1150°C in a N 2 /H 2 atmosphere. 23 The objectives of these studies were to form graphene at lower temperatures than those required for simple Si sublimation.…”

Section: Introductionmentioning

confidence: 99%

Improvements in graphene growth on 4H-SiC(0001) using plasma induced surface oxidation

Minami

Ito

Hosoo

et al. 2019

Journal of Applied Physics

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A Si-face 4H-SiC surface was modified by plasma oxidation followed by HF etching. The resulting surface was covered with a carbon overlayer composed of C-C bonded clusters and Si-O-C bonding from Si 4 C 4 O 4 and Si 4 C 4−x O 2 (x < 2), as evidenced by photoemission spectroscopy measurements and wetting properties. A trend was observed in which the thickness of the carbon overlayer was proportional to the SiO 2 thickness after plasma oxidation, indicating that the former could be controlled on the subnanometer scale by adjusting plasma conditions. After a subsequent annealing under ultrahigh vacuum, we found that graphene grew on the modified SiC surface without the formation of a pitting morphology, which is in contrast to the case using an untreated SiC substrate. Raman spectroscopy revealed that the former graphene includes fewer defects than the latter graphene. We discuss the microscopic mechanism by which reaction products composed of C-C and Si-O-C bonds form in the SiO 2 film near the SiO 2 /SiC interface via plasma oxidation as well as their influence on the subsequent growth of graphene.

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Synthesis of Few‐Layer Graphene‐on‐Insulator Films by Controllable C₄F₈ Plasma Etching SiC

Cited by 8 publications

References 33 publications

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

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

Plasma Modification of Graphene Nanoplatelets Surfaces

Improvements in graphene growth on 4H-SiC(0001) using plasma induced surface oxidation

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Synthesis of Few‐Layer Graphene‐on‐Insulator Films by Controllable C4F8 Plasma Etching SiC

Cited by 8 publications

References 33 publications

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

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

Plasma Modification of Graphene Nanoplatelets Surfaces

Improvements in graphene growth on 4H-SiC(0001) using plasma induced surface oxidation

Contact Info

Product

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Synthesis of Few‐Layer Graphene‐on‐Insulator Films by Controllable C₄F₈ Plasma Etching SiC