Anomalous piezoelectricity in two-dimensional graphene nitride nanosheets

Zelisko, Matthew; Hanlumyuang, Yuranan; Yang, Shubin; Liu, Yuanming; Lei, Chihou; Li, Jiangyu; Ajayan, Pulickel M.; Sharma, Pradeep

doi:10.1038/ncomms5284

Cited by 240 publications

(173 citation statements)

References 22 publications

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“…Benefitting from its ultrathin and easily bendable structure, the graphene membrane presents an ultrahigh direct piezoelectric coefficient (~37 nC N − 1 , approximately two orders of magnitude higher than traditional piezoelectric materials and functional graphene [16][17] ), although the converse piezoelectric coefficient is small (~12.5 μm V − 1 ) due to graphene's semi-metallic property and large quantum capacitance.…”

Section: Piezoelectric Coefficientmentioning

confidence: 99%

“…15 Achievement of piezoelectricity in previous pioneering works requires the functionalization or nanopatterning of graphene to break this centrosymmetry. 16,17 Furthermore, in its intrinsic (semi-)metallic states, graphene is clearly non-piezoelectric and/or non-flexoelectric. 17 In addition, its singleatom thickness leads to an ill-defined out-of plane strain gradient and a questionable breakage of the centrosymmetric flexoeletricity.…”

Section: Introductionmentioning

confidence: 99%

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Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

et al. 2015

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Piezoelectric materials used in the development of nanoscale mechanical sensors, actuators and energy harvesters have received much attention. More recently, devices made of graphene are of particular interest because of graphene's intriguing electronic and mechanical properties. Intrinsic graphene has long been considered devoid of the piezoelectric effect, although flexoelectricity has been exploited to demonstrate piezoelectricity in functionalized graphene and graphene nanoribbons. The perceived lack of this property has restricted graphene's use in nanoelectromechanical systems (NEMS) for electromechanical coupling purposes. Here an unprecedented two-dimensional (2D) piezoelectric effect on a strained/unstrained graphene junction is reported. In stark contrast to the bulk piezoelectric effect that results from the occurrence of electric dipole moments in solids, the 2D piezoelectric effect arises from the charge transfer along a work function gradient introduced by the biaxial-strainengineered band structure. The observed effect, termed the band-piezoelectric effect, exhibits an enormous magnitude due to the ultrathin structure of graphene. On the basis of the band-piezoelectric effect, a graphene nanogenerator and a pressure gauge were fabricated. The results not only provide a versatile NEMS platform for sensing, actuating and energy harvesting, but also pave the way for efficiently modulating graphene via strain engineering.

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Section: Piezoelectric Coefficientmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

et al. 2015

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“…The calculated vertical piezocoefficient was found to be about 1.4 nm/V, which is much higher than that of conventional piezoelectric materials [135]. Atomically-thin graphene nitride also exhibits anomalous piezoelectricity, due to the fact that a stable phase of a sheet features regularly spaced triangular holes, as indicated by ab initio calculations [136]. Directional dependent piezoelectric effects in chemical vapor deposited MoS 2 monolayers were measured through lateral PFM when an electric field was applied laterally across the flakes [131].…”

Section: Strain Engineering and Piezoresponse Force Microscopymentioning

confidence: 84%

Advanced Scanning Probe Microscopy of Graphene and Other 2D Materials

Musumeci

2017

Crystals

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Two-dimensional (2D) materials, such as graphene and metal dichalcogenides, are an emerging class of materials, which hold the promise to enable next-generation electronics. Features such as average flake size, shape, concentration, and density of defects are among the most significant properties affecting these materials' functions. Because of the nanoscopic nature of these features, a tool performing morphological and functional characterization on this scale is required. Scanning Probe Microscopy (SPM) techniques offer the possibility to correlate morphology and structure with other significant properties, such as opto-electronic and mechanical properties, in a multilevel characterization at atomic-and nanoscale. This review gives an overview of the different SPM techniques used for the characterization of 2D materials. A basic introduction of the working principles of these methods is provided along with some of the most significant examples reported in the literature. Particular attention is given to those techniques where the scanning probe is not used as a simple imaging tool, but rather as a force sensor with very high sensitivity and resolution.

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“…Previously, we have experimentally shown that vertically aligned CNTs exhibit a memristive switching associated with their strain and polarization [1][2][3]. Analysis of the literature [4][5][6] has shown that non-uniform strain in carbon nanostructures can lead to the appearance of a piezoelectric effect and the corresponding internal electric field in them. We put forward a proposal that the non-uniform strain of the CNT acts as an additional source of resistance which depends on the value of the current flowing.…”

Section: Introductionmentioning

confidence: 99%

The memristive behavior of non-uniform strained carbon nanotubes

Il’ina¹,

Il’in²,

Rudyk³

et al. 2018

Nanosystems: Phys. Chem. Math.

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It is shown that the non-uniform elastic strain is the memristive switching origin in carbon nanotubes (CNT). The dependence of the resistance ratio in high-and low-resistance states of the non-uniformly strained CNT on the value strain is obtained. The process of the strain redistribution and its effect on the conductivity of CNT under action of the external electric field strength is studied. The obtained results can be used to develop memristor structures with reproducible parameters based on non-uniformly strained of carbon nanotubes.

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Anomalous piezoelectricity in two-dimensional graphene nitride nanosheets

Cited by 240 publications

References 22 publications

Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

Advanced Scanning Probe Microscopy of Graphene and Other 2D Materials

The memristive behavior of non-uniform strained carbon nanotubes

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