Peeling of Long, Straight Carbon Nanotubes from Surfaces

Barker, Kane M.; Poggi, Mark A.; Lizárraga, Leonardo; Lillehei, Peter T.; Ferri, Antonio; Bottomley, Lawrence A.

doi:10.1155/2014/349453

Cited by 3 publications

(1 citation statement)

References 49 publications

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“…The objectives of the work presented herein were to determine the stiffness of CCNTs to axial compression and to correlate this stiffness with their composition/structure. Our approach involves attaching an individual nanotube to the tip of an atomic force microscope (AFM) probe and then using this instrument to apply a controlled mechanical load to the nanocoil [22][23][24]. Mechanical loading of straight or coiled nanotubes results in compression, buckling, and sliding on the substrate surface [9,22,23,[25][26][27][28][29][30][31][32].…”

Section: Introductionmentioning

confidence: 99%

Empirical Correlation of the Morphology of Coiled Carbon Nanotubes with Their Response to Axial Compression

Barber¹,

Boyles²,

Ferri³

et al. 2014

Journal of Nanotechnology

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The mechanical response of thirteen different helical multi-walled carbon nanocoils to axial compression is reported. Each nanocoil was attached to the apex of a cantilever probe tip; its dimensions and orientation relative to the tip apex were determined with scanning electron microscopy. The atomic force microscope was employed to apply a cyclic axial load on the nanocoil. Its mechanical response was determined by simultaneous collection of the thermal resonance frequency, displacement, and oscillation amplitude of the cantilever-nanotube system in real time. Depending upon compression parameters, each coil underwent buckling, bending, and slip-stick motion. Characteristic features in the thermal resonance spectrum and in the force and oscillation amplitude curves for each of these responses to induced stress are presented. Following compression studies, the structure and morphology of each nanocoil were determined by transmission electron microscopy. The compression stiffness of each nanocoil was estimated from the resonant frequency of the cantilever at the point of contact with the substrate surface. From this value, the elastic modulus of the nanocoil was computed and correlated with the coiled carbon nanotube's morphology.

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Section: Introductionmentioning

confidence: 99%

Empirical Correlation of the Morphology of Coiled Carbon Nanotubes with Their Response to Axial Compression

Barber¹,

Boyles²,

Ferri³

et al. 2014

Journal of Nanotechnology

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Peel tests for quantifying adhesion and toughness: A review

Case

Kinloch

Dillard

2023

Progress in Materials Science

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Adhesion energy of single wall carbon nanotube loops on various substrates

Ayari

Bellon

2015

Journal of Applied Physics

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International audienceThe physics of adhesion of one-dimensional nano structures such as nanotubes, nano wires, and biopolymers on different substrates is of great interest for the study of biological adhesion and the development of nano electronics and nano mechanics. In this paper, we present force spectroscopy experiments of individual single wall carbon nanotube loops using a home-made interferometric atomic force microscope. Characteristic force plateaus during the peeling process allow the quantitative measurement of the adhesion energy per unit length on various substrates: graphite, mica, platinum, gold, and silicon. Moreover, using a time-frequency analysis of the deflection of the cantilever, we estimate the dynamic stiffness of the contact, providing more information on the nanotube configurations and its intrinsic mechanical properties

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Peeling of Long, Straight Carbon Nanotubes from Surfaces

Cited by 3 publications

References 49 publications

Empirical Correlation of the Morphology of Coiled Carbon Nanotubes with Their Response to Axial Compression

Empirical Correlation of the Morphology of Coiled Carbon Nanotubes with Their Response to Axial Compression

Peel tests for quantifying adhesion and toughness: A review

Adhesion energy of single wall carbon nanotube loops on various substrates

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