Noncatalytic chemical vapor deposition of graphene on high-temperature substrates for transparent electrodes

Sun, Jie; Cole, Matthew T.; Lindvall, Niclas; Teo, Kenneth B. K.; Yurgens, A.

doi:10.1063/1.3675632

Cited by 66 publications

(15 citation statements)

References 28 publications

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“…Nevertheless, there is still scope for research in direct deposition of graphene and nanocrystalline graphene (NCG) layer onto insulator substrates [7]. There has been some research into metal-free deposition of graphene to achieve this goal, such as molecular beam epitaxy (MBE) [8,9], CVD [7,10,11] and various plasma-enhanced methods based on partially modified tools [12][13][14]. Although these films have typically a higher defect rate compared to graphene obtained by exfoliation or CVD, they can be suitable for applications such as saturable absorber in mode-locked lasers [15].…”

Section: Introductionmentioning

confidence: 99%

Metal-free plasma-enhanced chemical vapor deposition of large area nanocrystalline graphene

Schmidt

Cooke

et al. 2014

Mater. Res. Express

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This paper reports on large area, metal-free deposition of nanocrystalline graphene (NCG) directly onto wet thermally oxidized 150 mm silicon substrates using parallel-plate plasma-enhanced chemical vapor deposition. Thickness nonuniformities as low as 13% are achieved over the whole substrate. The cluster size L a of the as-obtained films is determined from Raman spectra and lies between 1.74 and 2.67 nm. The film uniformity was further confirmed by Raman mapping. The sheet resistance R sq of 3.73 Ω k and charge carrier mobility μ of − − 2.49 cm V s 2 1 1 are measured. We show that the NCG films can be readily patterned by reactive ion etching. NCG is also successfully deposited onto quartz and sapphire substrates and showed >85% optical transparency in the visible light spectrum.

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Section: Introductionmentioning

confidence: 99%

Metal-free plasma-enhanced chemical vapor deposition of large area nanocrystalline graphene

Schmidt

Cooke

et al. 2014

Mater. Res. Express

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“…Another way is to grow graphene directly on dielectric insulators without using any metal catalyst, which is a much-needed technique for its electronic application. Recently, many research groups have pursued the direct growth of graphene on various dielectric substrates including hexagonal boron nitride (h-BN) [7, 8], glass [9–11], quartz [12], sapphire [13, 14], Si 3 N 4 [15–17], SiO 2 [18–21], and high-k dielectrics such as MgO [22, 23], ZrO 2 [23], and TiO 2 [24], using CVD without using metal catalysts. However, the as-grown graphene on above substrates exhibits poor quality, which is comparable neither with that of graphene grown on metal substrates such as Ni [1] and Cu [3] nor with epitaxial graphene on SiC [25].…”

Section: Introductionmentioning

confidence: 99%

Direct Growth of Graphene on Insulator Using Liquid Precursor Via an Intermediate Nanostructured State Carbon Nanotube

Nayak

2019

Nanoscale Res Lett

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Synthesis of high-quality graphene layers on insulating substrates is highly desirable for future graphene-based high-speed electronics. Besides the use of gaseous hydrocarbon sources, solid and liquid hydrocarbon sources have recently shown great promises for high-quality graphene growth. Here, I report chemical vapor deposition growth of mono- to few-layer graphene directly on SiO2 substrate using ethanol as liquid hydrocarbon feedstock. The growth process of graphene has been systematically investigated as a function of annealing temperature as well as different seed layers. Interestingly, it was found that the carbon atoms produced by thermal decomposition of ethanol form sp2 carbon network on SiO2 surface thereby forming nanographene flakes via an intermediate carbon-based nanostructured state carbon nanotube. This work might pave the way to an understanding for economical and catalyst-free graphene growth compatible with current silicon-processing techniques, and it can be applied on a variety of insulating surfaces including quartz, sapphire, and fused silica.Electronic supplementary materialThe online version of this article (10.1186/s11671-019-2935-9) contains supplementary material, which is available to authorized users.

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“…20 Its remarkable characteristics, including its high carrier mobility, 21 broad spectral absorption wavelength, and fast carrier transport, have attracted numerous researchers interested in building hybrid devices. [22][23][24] Prior researchers have used graphene as a transparent contact with GaN NRs due to its high conductivity and low optical absorbance (approximately 2.3%) for light in a wavelength range of 300 nm to the nearinfrared, 25 and produced around 25 A/W responsivity as a result. 26 Others have compared photocurrent production and responsivity in GaN PDs with and without graphene, determining that a GaN PD with graphene produces 35Â more photocurrent and higher responsivity than it does without graphene.…”

mentioning

confidence: 99%

A highly sensitive, large area, and self-powered UV photodetector based on coalesced gallium nitride nanorods/graphene/silicon (111) heterostructure

Zulkifli

Park

Min

et al. 2020

Applied Physics Letters

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In this paper, we demonstrate an ultraviolet photodetector (UV-PD) that uses coalesced gallium nitride (GaN) nanorods (NRs) on a graphene/Si (111) substrate grown by plasma-assisted molecular beam epitaxy. We report a highly sensitive, self-powered, and hybrid GaN NR/graphene/Si (111) PD with a relatively large 100 mm 2 active area, a high responsivity of 17.4 A/W, a high specific detectivity of 1.23 Â 10 13 Jones, and fast response speeds of 13.2/13.7 ls (20 kHz) under a UV light of 355 nm at zero bias voltage. The results show that the thin graphene acts as a perfect interface for GaN NRs, encouraging growth with minimum defects on the Si substrate. Our results suggest that the GaN NR/graphene/Si (111) heterojunction has a range of interesting properties that make it well-suited for a variety of photodetection applications.

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Noncatalytic chemical vapor deposition of graphene on high-temperature substrates for transparent electrodes

Cited by 66 publications

References 28 publications

Metal-free plasma-enhanced chemical vapor deposition of large area nanocrystalline graphene

Metal-free plasma-enhanced chemical vapor deposition of large area nanocrystalline graphene

Direct Growth of Graphene on Insulator Using Liquid Precursor Via an Intermediate Nanostructured State Carbon Nanotube

A highly sensitive, large area, and self-powered UV photodetector based on coalesced gallium nitride nanorods/graphene/silicon (111) heterostructure

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