Nanoscale mechanisms of CNT growth and etching in plasma environment

Khalilov, Umedjon; Bogaerts, Annemie; Hussain, Shahzad; Kovačević, Eva; Brault, Pascal; Boulmer‐Leborgne, Chantal; Neyts, Erik C.

doi:10.1088/1361-6463/aa6733

Cited by 14 publications

(14 citation statements)

References 76 publications

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“…The VGNs were synthesized using a cold-wall CVD by radio frequency capacitively coupled plasma (RFCCP) operated at 13.56 MHz RF power. The detailed scheme of experimental setup has been presented in our previous studies [33][34][35][36][37]. Silicon wafers covered with 200 nm thick aluminium (Al) are used as the substrate for synthesizing VGNs.…”

Section: 1synthesis Of Vgnsmentioning

confidence: 99%

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Low-temperature low-power PECVD synthesis of vertically aligned graphene

et al. 2020

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The need for 2D vertical graphene nanosheets (VGNs) is driven by its great potential in diverse energy, electronics, and sensor applications, wherein many cases a low-temperature synthesis is preferred due to requirements of the manufacturing process. Unfortunately, most of today's known methods, including plasma, require either relatively high temperatures or high plasma powers. Herein, we report on a controllable synthesis of VGNs at a pushed down lowtemperature boundary for synthesis, the low temperatures (450 o C) and low plasma powers (30 W) using capacitively coupled plasma (CCP) driven by radio-frequency power at 13.56 MHz. The strategies implemented also include unrevealing the role of Nickel (Ni) catalyst thin film on the substrates (Si/Al). It was found that the Ni catalyst on Si/Al initiates the nucleation/growth of VGNs at 450 °C in comparison to the substrates without Ni catalyst.With increasing temperature, the graphene nanosheets become bigger in size, well-structured and well separated. The role of Ni catalysts is hence to boost the growth rate, density, and quality of the growing VGNs. Furthermore, this CCP method can be used to synthesize VGNs at the lowest temperatures possible so far on a variety of substrates and provide new opportunities in the practical application of VGNs.

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Section: 1synthesis Of Vgnsmentioning

confidence: 99%

“…Thus, the hydrogen plasma treatment is almost considered as a standard pre-treatment, and several morphologies have been documented by this method [33]. On the other hand, an argon plasma, which is more effective than hydrogen plasma for the cleaning or etching, is very rarely used for the pre-treatments.…”

Section: Introductionmentioning

confidence: 99%

Low-temperature low-power PECVD synthesis of vertically aligned graphene

et al. 2020

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“…It remains very challenging, however, to confirm the underlying mechanisms of the above mentioned processes on the nano/micro-scale. In this regard, Molecular Dynamics (MD) simulations have been an invaluable tool, not only for the study of graphite/graphene systems as described below, but also for closely related materials such as carbon nanotubes 23 – 25 and nanocrystalline diamond. 26 In graphene/graphite etching simulations, pure graphite or pre-constructed amorphous carbon (a-C:H) samples (to which graphite samples are found to evolve) 15 are bombarded with energetic hydrogen, thus providing insight into the elementary reactions and emission processes at the atomic level.…”

Section: Introductionmentioning

confidence: 99%

Atomistic simulations of graphite etching at realistic time scales

et al. 2017

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“…Tip-growth requires detachment of the nanoparticle from the substrate. In order to achieve this, oxidized substrates, such as alumina, coated with thin layers of catalyzer-material are often used to enable nucleation and the formation of non-aggregated and detachable nanoparticles with a narrow distribution of size by annealing, see [26], Figure 4.Therefore, it is expected that non-metallic substrates, e.g., with oxidized surfaces, may promote tip-growth in vacuum electronic products. In an X-ray tube, metallic vapor from various sources, notably tungsten vapor and small atom clusters from the heated focal spot, may condense on negative electrodes, nucleate and grow to build nanoparticles of a critical size on the order of a few dozen nanometers.…”

Section: Nanoparticle Contaminationmentioning

confidence: 99%

Electric Field Enhancing Artifacts as Precursors for Vacuum High-Voltage Breakdown

Behling¹

2019

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Abrupt formation of plasma in a high-voltage insulating vacuum gap and subsequent discharge of electrodes limits the reliability of a class of vacuum electronic devices, such as X-ray tubes. It has been suggested that electron field emission from negatively charged electrodes would precede and initiate such discharge. Heating and evaporation of material upon field emission would cause dense plasma to develop in periods of nanoseconds. High-pressure plasma would expand from the cathode, eventually bridging the gap. Nevertheless, the very reason for the unredictable initial development of discharge events after long periods of reliable operation is still matter of debate. Experience from industrial processes suggests hydrocarbon contamination to degrade the electric stability of high-voltage gaps. While former attempts aimed at explaining high field emission by carbonaceous 2D structures or surface resonance effects, this paper discusses whether 3D structures may grow slowly, until their evaporation in a matter of nanoseconds. Similar to the production of carbon nanotubes, protruding structures might comprise carbon and, in addition, metallic nanoparticles, which would boost production of vapor during their explosion. The hypothesis was tested by scanning electron and energy-dispersive X-ray inspection of two cathodes of medical X-ray tubes, covered with metallic seed nanoparticles, which served as model systems. A third cleaner cathode was inspected for comparison. Although certain suggested conditions of carbon feed, elevated substrate temperature and nanoparticle contamination of the surfaces were met, images showed only a very weak sign of growth of suspicious carbon structures. It seems, therefore, unlikely that CNT-like structures are a major cause of high-voltage breakdown between electrodes of X-ray tubes.

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Nanoscale mechanisms of CNT growth and etching in plasma environment

Cited by 14 publications

References 76 publications

Low-temperature low-power PECVD synthesis of vertically aligned graphene

Low-temperature low-power PECVD synthesis of vertically aligned graphene

Atomistic simulations of graphite etching at realistic time scales

Electric Field Enhancing Artifacts as Precursors for Vacuum High-Voltage Breakdown

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