Electromechanical properties of single-walled carbon nanotube devices on micromachined cantilevers

Jeon, Eun-Kyoung; Park, Chan-Hyun; Lee, Jung A; Kim, Minseok; Lee, Kwang-Cheol; So, Hye‐Mi; Ahn, Chang-Hoi; Chang, Hyunju; Kong, Ki−jeong; Kim, Ju‐Jin; Lee, Jun Young

doi:10.1088/0960-1317/22/11/115010

Cited by 5 publications

(2 citation statements)

References 23 publications

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“…Tips from atomic force microscopy (AFM) were used to deflect suspended individual SWCNT and caused a decrease of two orders of magnitude of conductivity due to the formation of local sp 3 bonds between tube and tip [28]. When applying reversible deformations and compressive strains (bending) on individual SWCNTs with an AFM tip alterations of the band gap and the conductivity were observed [29]. A strain gauge was theoretically predicted by the tight-binding approach and for SWCNTs with diameter larger than 1 nm it was found to be chirality dependent [30].…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Flexible Carbon Nanotube Films for High Performance Strain Sensors

Kanoun

Müller

Benchirouf

et al. 2014

Sensors

268

138

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Compared with traditional conductive fillers, carbon nanotubes (CNTs) have unique advantages, i.e., excellent mechanical properties, high electrical conductivity and thermal stability. Nanocomposites as piezoresistive films provide an interesting approach for the realization of large area strain sensors with high sensitivity and low manufacturing costs. A polymer-based nanocomposite with carbon nanomaterials as conductive filler can be deposited on a flexible substrate of choice and this leads to mechanically flexible layers. Such sensors allow the strain measurement for both integral measurement on a certain surface and local measurement at a certain position depending on the sensor geometry. Strain sensors based on carbon nanostructures can overcome several limitations of conventional strain sensors, e.g., sensitivity, adjustable measurement range and integral measurement on big surfaces. The novel technology allows realizing strain sensors which can be easily integrated even as buried layers in material systems. In this review paper, we discuss the dependence of strain sensitivity on different experimental parameters such as composition of the carbon nanomaterial/polymer layer, type of polymer, fabrication process and processing parameters. The insights about the relationship between film parameters and electromechanical properties can be used to improve the design and fabrication of CNT strain sensors.

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Section: Theoretical Backgroundmentioning

confidence: 99%

Flexible Carbon Nanotube Films for High Performance Strain Sensors

Kanoun

Müller

Benchirouf

et al. 2014

Sensors

268

138

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“…The last two decades have witnessed the extensive research on nanomaterials because of their exceptional promise in science and technology. Based on structural dimension, existing nanomaterials fall into four categories of nanostructures: zero-dimensional structures (e.g., nanoparticles, nanospheres, and isolated molecules) [ 1 ], one-dimensional structures (e.g., nanowires, nanobelts, nanotubes, and nanoribbons) [ 2 – 4 ], two-dimensional structures (e.g., nanofilms, grapheme, and molybdenum disulfide) [ 5 , 6 ], and three-dimensional structures (e.g., nanocombs, nanoflowers, and nanocups) [ 7 – 9 ]. Due to their superior physical properties and unique nanoscale morphologies, these nanomaterials have been widely used for a variety of applications such as next-generation electronics [ 10 ], sustainable energy [ 11 ], biosensing [ 12 ], and (opto) electronics [ 13 ].…”

Section: Introductionmentioning

confidence: 99%

Recent Advances on SEM-Based In Situ Multiphysical Characterization of Nanomaterials

Liu

2021

Scanning

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Functional nanomaterials possess exceptional mechanical, electrical, and optical properties which have significantly benefited their diverse applications to a variety of scientific and engineering problems. In order to fully understand their characteristics and further guide their synthesis and device application, the multiphysical properties of these nanomaterials need to be characterized accurately and efficiently. Among various experimental tools for nanomaterial characterization, scanning electron microscopy- (SEM-) based platforms provide merits of high imaging resolution, accuracy and stability, well-controlled testing conditions, and the compatibility with other high-resolution material characterization techniques (e.g., atomic force microscopy), thus, various SEM-enabled techniques have been well developed for characterizing the multiphysical properties of nanomaterials. In this review, we summarize existing SEM-based platforms for nanomaterial multiphysical (mechanical, electrical, and electromechanical) in situ characterization, outline critical experimental challenges for nanomaterial optical characterization in SEM, and discuss potential demands of the SEM-based platforms to characterizing multiphysical properties of the nanomaterials.

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