Control of surface wettability via strain engineering

Xiong, Wei; Liu, Jefferson Zhe; Zhang, Zhiliang; Zhen, Quan-Shui

doi:10.1007/s10409-013-0063-9

Cited by 19 publications

(8 citation statements)

References 47 publications

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“…For example, a superhydrophobic graphene surface has been synthesized by chemical treatments. 8,9 In addition to chemical methods, mechanical strategies have been developed to adjust wetting properties of graphene surface by introducing surface patterns 10 and local defects. 11 The wettability of water droplet on a single suspended sheet of graphene cannot be measured easily and precisely thanks to a high flexibility of graphene sheet, and more than one layer graphene is often employed in practice.…”

Section: Introductionmentioning

confidence: 99%

Wettability of water droplet on misoriented graphene bilayer sructure: A molecular dynamics study

Liu

2015

AIP Advances

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Wettability of water droplet on misoriented graphene bilayer sructure: A molecular dynamics study Graphene continues to attract growing attention with its exceptional physical and mechanical properties, and more than one layer graphene structure with an orientation mismatch is often involved in practice. Using molecular dynamics (MD) simulations, we report the wettability of water droplet on a misoriented graphene bilayer structure. The contact angle of water droplet will change with the interlayer orientation of bilayer graphene structure, and reaches a maximum of 97.97 ± 1.15• at orientation mismatch of 40•

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Section: Introductionmentioning

confidence: 99%

Wettability of water droplet on misoriented graphene bilayer sructure: A molecular dynamics study

Liu

2015

AIP Advances

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“…The question of how to drive a relatively large nanoparticle is put forward. Inspired by a study demonstrating that the tension strain in a graphene sheet could change the wettability of a surface based on a change in the atomistic lattice 28 , we adopt the novel idea to study the possible motion of large particles. Cases of graphene substrate with and without pre-tension are analyzed.…”

Section: Resultsmentioning

confidence: 99%

A new technique for nanoparticle transport and its application in a novel nano-sieve

Wang

Peng

et al. 2018

Sci Rep

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A new technique is proposed to transport and further classify nanoparticles of different sizes. A graphene sheet is used as the substrate; a nanoparticle is placed on the substrate and a sliding block is located below the substrate. As the sliding block moves under the graphene substrate, a driving force is yielded from the van der Waals interaction between the sliding block and the nanoparticle. The effects of the pre-tension of the graphene substrate, size and number of layers of the nanoparticle, slip velocity, the interface commensurability and temperature on nanoparticle transportation are systematically investigated. It is found that a pre-tensioned graphene substrate could provide easier nanoparticle transport. The initial movement of the nanoparticle depends on the competition between the in-plane force and the driving force, while the subsequent transport depends on the slip velocity of the sliding block and the viscous damping force. Based on such a new transport mechanism, a novel nano-sieve can be designed, with which nanoparticles of different sizes can be screened and classified spontaneously. Our findings may be useful for promising designs of transportation, manipulation and classification of nanoparticles.

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“…Following the deformation of graphene, it becomes more reactive, and its wettability with respect to the HF-containing solution increases. 42,43 The wettability of fluorinated graphene with respect to water is higher in comparison with graphene. Due to the change in the flake surface wettability the penetration of the HF-containing solution into flakes can become accelerated.…”

Section: Discussionmentioning

confidence: 99%

Fluorinated graphene dielectric films obtained from functionalized graphene suspension: preparation and properties

Nebogatikova

Antonova

Prinz

et al. 2015

Phys. Chem. Chem. Phys.

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In the present study, we have examined the interaction between a suspension of graphene in dimethylformamide and an aqueous solution of hydrofluoric acid, which was found to result in partial fluorination of suspension flakes. A considerable decrease in the thickness and lateral size of the graphene flakes (up to 1-5 monolayers in thickness and 100-300 nm in diameter) with increasing duration of fluorination treatment is found to be accompanied by a simultaneous transition of the flakes from the conducting to the insulating state. Smooth and uniform insulating films with a roughness of ∼2 nm and thicknesses down to 20 nm were deposited from the suspension on silicon. The electrical and structural properties of the films suggest their use as insulating elements in thin-film nano- and microelectronic device structures. In particular, it was found that the films prepared from the fluorinated suspension display rather high breakdown voltages (field strength of (1-3) × 10(6) V cm(-1)), ultralow densities of charges in the film and at the interface with the silicon substrate in metal-insulator-semiconductor structures (∼(1-5) × 10(10) cm(-2)). Such excellent characteristics of the dielectric film can be compared only to well-developed SiO2 layers. The films from the fluorinated suspension are cheap, practically feasible and easy to produce.

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Control of surface wettability via strain engineering

Cited by 19 publications

References 47 publications

Wettability of water droplet on misoriented graphene bilayer sructure: A molecular dynamics study

Wettability of water droplet on misoriented graphene bilayer sructure: A molecular dynamics study

A new technique for nanoparticle transport and its application in a novel nano-sieve

Fluorinated graphene dielectric films obtained from functionalized graphene suspension: preparation and properties

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