Elastic straining of free-standing monolayer graphene

Cao, Ke; Feng, Shizhe; Han, Ying; Gao, Libo; Ly, Thuc Hue; Xu, Zhiping; Lü, Yang

doi:10.1038/s41467-019-14130-0

Cited by 248 publications

(185 citation statements)

References 47 publications

(72 reference statements)

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“…For example, the DFT and molecular dynamics simulations predict that it can be stretched up to about 20-30%, without being damaged [1]. The experimental measurements demonstrate a good agreement with the theoretical estimations, while the robust engineering results indicate on sample-wide elastic strain ∼6% [2]. Evidently, transforming the flat surface to the curved one, one creates the strain that affects the graphene properties.…”

Section: Introductionmentioning

confidence: 60%

On Symmetry Properties of The Corrugated Graphene System

2020

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The properties of the ballistic electron transport through a corrugated graphene system are analysed from the symmetry point of view. The corrugated system is modelled by a curved surface (an arc of a circle) connected from both sides to flat sheets. The spin–orbit couplings, induced by the curvature, give rise to equivalence between the transmission (reflection) probabilities of the transmitted (reflected) electrons with the opposite spin polarisation, incoming from opposite system sides. We find two integrals of motion that explain the chiral electron transport in the considered system.

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Section: Introductionmentioning

confidence: 60%

On Symmetry Properties of The Corrugated Graphene System

2020

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“…Therefore, without doubt, it will be challenging to experimentally verify our predictions, both in terms of membrane fabrication and precise application of strains. Nonetheless, recent advances in fabrication [15,16] and strain actuation at the nanoscale [20,33] suggest that rapid progress is being made toward the possibility of experimentally exploring strain-gated nanofluidic systems.…”

Section: Discussionmentioning

confidence: 99%

“…Uniaxial in-plane tensile strains are applied to the membrane as described earlier [10] and in the SI. Strain magnitudes are varied up to 0.04, well within graphene's experimentally observed limits of elasticity [20]. Figure 1.…”

Section: Introductionmentioning

confidence: 87%

Ion transport across solid-state ion channels perturbed by directed strain

et al. 2020

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We combine quantum-chemical calculations and molecular dynamics simulations to consider aqueous ion flow across non-axisymmetric nanopores in monolayer graphene and MoS2. When the pore-containing membrane is subject to uniaxial tensile strains applied in various directions, the corresponding permeability exhibits considerable directional dependence. This anisotropy is shown to arise from directed perturbations of the local electrostatics by the corresponding pore deformation, as enabled by the pore edge geometries and atomic compositions. By considering nanopores with ionic permeability that depends on the strain direction, we present model systems that may yield a detailed understanding of the structure-function relationship in solid-state and biological ion channels. Specifically, the observed anisotropic effects potentially enable the use of permeation measurements across strained membranes to obtain directional profiles of ion-pore energetics as contributed by groups of atoms or even individual atoms at the pore edge. The resulting insight may facilitate the development of subnanoscale pores with novel functionalities arising from locally asymmetric pore edge features.

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“…Further, the relative equivalent complex permittivity of graphene can be calculated by using ε g = 1 + jσ g /(ε 0 ωd) [12], where d = 0.335 nm is the thickness of monolayer graphene [38,39]. Within the random-phase approximation, the dynamic optical response of graphene can be derived from the Kubo's formula consisting of the interband and intraband contributions in the infrared ranges, that is σ g = σ intra + σ inter , and the surface conductivity of graphene is given as [40]:…”

Section: Surface Conductivity Of Graphenementioning

confidence: 99%

Graphene-Coated Nanowire Waveguides and Their Applications

Teng

Wang

2020

Nanomaterials

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In recent years, graphene-coated nanowires (GCNWs) have attracted considerable research interest due to the unprecedented optical properties of graphene in terahertz (THz) and mid-infrared bands. Graphene plasmons in GCNWs have become an attractive platform for nanoscale applications in subwavelength waveguides, polarizers, modulators, nonlinear devices, etc. Here, we provide a comprehensive overview of the surface conductivity of graphene, GCNW-based plasmon waveguides, and applications of GCNWs in optical devices, nonlinear optics, and other intriguing fields. In terms of nonlinear optical properties, the focus is on saturable absorption. We also discuss some limitations of the GCNWs. It is believed that the research of GCNWs in the field of nanophotonics will continue to deepen, thus laying a solid foundation for its practical application.

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Elastic straining of free-standing monolayer graphene

Cited by 248 publications

References 47 publications

On Symmetry Properties of The Corrugated Graphene System

On Symmetry Properties of The Corrugated Graphene System

Ion transport across solid-state ion channels perturbed by directed strain

Graphene-Coated Nanowire Waveguides and Their Applications

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