Liquids relax and unify strain in graphene

Belyaeva, L. A.; Soleimani, Alireza; Methorst, Jeroen; Risselada, Herre Jelger; Schneider, Grégory F.

doi:10.1038/s41467-020-14637-x

Cited by 20 publications

(17 citation statements)

References 69 publications

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“…Furthermore, for few-layer graphene films with less structural rigidity, modification of the float transfer interface is essential. To reduce the surface tension responsible for graphene film dissociation, a water-immiscible organic solvent such as hexane [30] or cyclohexane [46,83] may be applied to allow interfacial caging of the graphene at an intermediate interface. By changing the separation interface from an air-water boundary with surface tension of 72 mN m −1 to a solvent-water boundary with surface tension <50 mN m −1 , [46,83,84] float transfer of few-layer graphene films may be realized.…”

Section: Discussionmentioning

confidence: 99%

“…To reduce the surface tension responsible for graphene film dissociation, a water-immiscible organic solvent such as hexane [30] or cyclohexane [46,83] may be applied to allow interfacial caging of the graphene at an intermediate interface. By changing the separation interface from an air-water boundary with surface tension of 72 mN m −1 to a solvent-water boundary with surface tension <50 mN m −1 , [46,83,84] float transfer of few-layer graphene films may be realized. We anticipate that future work to better understand the bifacial separation mechanism and to optimize its performance with these modifications will enable PMMA-free float transfer of thinner multilayer, or even monolayer, graphene films.…”

Section: Discussionmentioning

confidence: 99%

“…Similarly, we anticipate improved properties of the float transfer graphene film, as circumventing the polymer support may allow relaxation of the inherent mechanical strain from the native growth substrate. [45,46] Due to the multilayer nature of the films, strain information cannot confidently be extracted via Raman peak shift analysis; [47,48] however, a relative improvement in the inherent surface quality of float transferred graphene is anticipated in the electronic film properties.…”

Section: Characterization Of Preferred and Non-preferred Multilayer Gmentioning

confidence: 99%

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Bifacial Multilayer Graphene Float Transfer

Andrade

Folkson

Boukhicha

et al. 2020

Adv Funct Materials

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A method for graphene transfer which is referred to as "bifacial transfer" that allows transfer of multilayer chemical vapor deposition (CVD) graphene from both sides of a native metal substrate, such as an as-received nickel catalyst, is presented. In traditional transfer methods, the graphene on the "non-preferred" side, that is, the bottom of the substrate, is removed with oxygen plasma before removal of the metal catalyst in etchant solution. Although this treatment prevents undesired aggregation of the graphene films, it fails to utilize both sides of CVD-grown graphene. The bifacial transfer method reduces the cost of multilayer graphene by allowing the transfer of graphene from both sides of the substrate. The quality of graphene transferred from both sides onto target glass and polymer substrates is compared. The results of optical microscopy, confocal Raman spectroscopy, atomic force microscopy, and electronic transport measurements suggest that the quality of the multilayer graphene on the "non-preferred" side does not differ significantly from that of the "preferred" side. This method will allow more efficient and cost-effective use of graphene by doubling the usable graphene per area of growth substrate, and by eliminating the need for intermediate sacrificial transfer substrates such as poly(methyl methacrylate).

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Characterization Of Preferred and Non-preferred Multilayer Gmentioning

confidence: 99%

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Bifacial Multilayer Graphene Float Transfer

Andrade

Folkson

Boukhicha

et al. 2020

Adv Funct Materials

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“…Similar Raman spectra for DH-G and untreated G also corroborate the restored carbon lattices. In particular, the slight change in the width and intensity of the D peak in DH-G can be attributed to the strain in graphene introduced during the annealing process [46]. Strain fields in graphene induced by the underlying support are able to activate intrinsic defects like interstitials and vacancies along the grain boundaries, which normally does not contribute to the D peak in non-strained graphene [47].…”

Section: Dehydrogenated Graphene For High Quality Electronicsmentioning

confidence: 99%

Reversible hydrogenation restores defected graphene to graphene

et al. 2021

Self Cite

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Graphene as a two-dimensional material is prone to hydrocarbon contaminations, which can significantly alter its intrinsic electrical properties. Herein, we implement a facile hydrogenation-dehydrogenation strategy to remove hydrocarbon contaminations and preserve the excellent transport properties of monolayer graphene. Using electron microscopy we quantitatively characterized the improved cleanness of hydrogenated graphene compared to untreated samples. In situ spectroscopic investigations revealed that the hydrogenation treatment promoted the adsorption ofytyt water at the graphene surface, resulting in a protective layer against the re-deposition of hydrocarbon molecules. Additionally, the further dehydrogenation of hydrogenated graphene rendered a more pristine-like basal plane with improved carrier mobility compared to untreated pristine graphene. Our findings provide a practical post-growth cleaning protocol for graphene with maintained surface cleanness and lattice integrity to systematically carry a range of surface chemistry in the form of a well-performing and reproducible transistor.

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“…6(a) and 6(b)). 103 Similarly, Judek and coworkers studied the graphene-germanium interaction by Raman spectroscopy. The defects and strain increased for Hydrogen insert during the cooling process.…”

Section: Strain and Dopingmentioning

confidence: 99%

Applications of Raman spectroscopy in two-dimensional materials

Yin

Lin

2020

J. Innov. Opt. Health Sci.

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At present, two-dimensional (2D) materials have shown great application potential in numerous fields based on their physical chemical and electronic properties. Raman spectroscopy and derivative techniques are effective tools for characterizing 2D materials. Raman spectroscopy conveys lots of knowledge on 2D materials, including layer number, doping type, strain and interlayer coupling. This review summarized advanced applications of Raman spectroscopy in 2D materials. The challenges and possible applied directions of Raman spectroscopy to 2D materials are discussed in detail.

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Liquids relax and unify strain in graphene

Cited by 20 publications

References 69 publications

Bifacial Multilayer Graphene Float Transfer

Bifacial Multilayer Graphene Float Transfer

Reversible hydrogenation restores defected graphene to graphene

Applications of Raman spectroscopy in two-dimensional materials

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