Synthesis of Large-Area Single-Crystal Graphene

Wang, Meihui; Luo, Da; Wang, Bin; Ruoff, Rodney S.

doi:10.1016/j.trechm.2020.10.009

Cited by 31 publications

(24 citation statements)

References 118 publications

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“…The epitaxial growth of single crystal graphene on a single crystal metal substrate, especially a single crystal Cu(111) foil, has been reported. [ 15,29–32 ] Since both graphene and the Cu substrate are single crystals, the influence by defects and GBs in both graphene and Cu can be minimized, thus this single crystal graphene‐coated Cu(111) is a good platform to investigate whether it is possible to minimize or even eliminate oxidation of the Cu using graphene as a barrier. Xu et al.…”

Section: Introductionmentioning

confidence: 99%

“…The epitaxial growth of single crystal graphene on a single crystal metal substrate, especially a single crystal Cu(111) foil, has been reported. [15,[29][30][31][32] Since both graphene and the Cu substrate are single crystals, the influence by defects and GBs in both graphene and Cu can be minimized, thus this single crystal graphene-coated Cu(111) is a good platform to investigate whether it is possible to minimize or even eliminate oxidation of the Cu using graphene as a barrier. Xu et al reported that asgrown single crystal graphene islands on a Cu(111) foil protect the Cu surface from wet-oxidation by preventing water and/or O 2 from diffusing to the graphene/Cu(111) interface when exposed to humid air (relative humidity > 80%) at 50 °C.…”

Section: Introductionmentioning

confidence: 99%

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The Wet‐Oxidation of a Cu(111) Foil Coated by Single Crystal Graphene

Luo

Wang

et al. 2021

Advanced Materials

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The wet‐oxidation of a single crystal Cu(111) foil is studied by growing single crystal graphene islands on it followed by soaking it in water. 18O‐labeled water is also used; the oxygen atoms in the formed copper oxides in both the bare and graphene‐coated Cu regions come from water. The oxidation of the graphene‐coated Cu regions is enabled by water diffusing from the edges of graphene along the bunched Cu steps, and along some graphene ripples where such are present. This interfacial diffusion of water can occur because of the separation between the graphene and the “step corner” of bunched Cu steps. Density functional theory simulations suggest that adsorption of water in this gap is thermodynamically stable; the “step‐induced‐diffusion model” also applies to graphene‐coated Cu surfaces of various other crystal orientations. Since bunched Cu steps and graphene ripples are diffusion pathways for water, ripple‐free graphene is prepared on ultrasmooth Cu(111) surfaces and it is found that the graphene completely shields the underlying Cu from wet‐oxidation. This study greatly deepens the understanding of how a graphene‐coated copper surface is oxidized, and shows that graphene completely prevents the oxidation when that surface is ultrasmooth and when the graphene has no ripples or wrinkles.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Wet‐Oxidation of a Cu(111) Foil Coated by Single Crystal Graphene

Luo

Wang

et al. 2021

Advanced Materials

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“…Mass production schemes discussed in this section includes graphene transfer process using roll-to-roll (R2R) processing, graphene growth and MEMS device fabrication on transition metal thin films for transfer-free process, controlled graphene growth on single-crystalline films, strain engineering on the substrate, and other approaches. [183][184][185]. Two data points with asterisks represent CVD growth of graphene by accelerated growth technique [186,187].…”

Section: Proposed Solutionsmentioning

confidence: 99%

“…Cu (111) and graphene have 4% lattice mismatch, and as temperature is highly elevated during graphene growth, the domains connect with each other creating seamless boundaries. It has been reported merging of grain boundaries is critical to electrical quality of graphene as electron scattering is observed near grain boundaries and wrinkles [5,184,214]. [209].…”

Section: Substrate Engineering For Single-seed Growth For Single Crystal Graphene (Scg)mentioning

confidence: 99%

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Towards Repeatable, Scalable Graphene Integrated Micro-Nano Electromechanical Systems (MEMS/NEMS)

et al. 2021

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The demand for graphene-based devices is rapidly growing but there are significant challenges for developing scalable and repeatable processes for the manufacturing of graphene devices. Basic research on understanding and controlling growth mechanisms have recently enabled various mass production approaches over the past decade. However, the integration of graphene with Micro-Nano Electromechanical Systems (MEMS/NEMS) has been especially challenging due to performance sensitivities of these systems to the production process. Therefore, ability to produce graphene-based devices on a large scale with high repeatability is still a major barrier to the commercialization of graphene. In this review article, we discuss the merits of integrating graphene into Micro-Nano Electromechanical Systems, current approaches for the mass production of graphene integrated devices, and propose solutions to overcome current manufacturing limits for the scalable and repeatable production of integrated graphene-based devices.

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Graphene‐Based Microwave Circuits: A Review

et al. 2022

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adma.202108473.Over the past two decades, research on 2D materials has received much interest. Graphene is the most promising candidate regarding high-frequency applications thus far due to is high carrier mobility. Here, the research about the employment of graphene in micro-and millimeter-wave circuits is reviewed. The review starts with the different methodologies to grow and transfer graphene, before discussing the way graphene-based field-effecttransistors (GFETs) and diodes are built. A review on different approaches for realizing these devices is provided before discussing the employment of both GFETs and graphene diodes in different micro-and millimeter-wave circuits, showing the possibilities but also the limitations of this 2D material for highfrequency applications.

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Synthesis of Large-Area Single-Crystal Graphene

Cited by 31 publications

References 118 publications

The Wet‐Oxidation of a Cu(111) Foil Coated by Single Crystal Graphene

The Wet‐Oxidation of a Cu(111) Foil Coated by Single Crystal Graphene

Towards Repeatable, Scalable Graphene Integrated Micro-Nano Electromechanical Systems (MEMS/NEMS)

Graphene‐Based Microwave Circuits: A Review

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