Aligned carbon nanotube array stiffness from stochastic three-dimensional morphology

Stein, Itai Y.; Lewis, Diana J.; Wardle, Brian L.

doi:10.1039/c5nr06436h

Cited by 45 publications

(96 citation statements)

References 41 publications

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Section: Behavior In Tensionmentioning

confidence: 99%

“…Recent simulations of CNT vertical arrays show that the effective modulus can be reduced by several orders of magnitude due to CNT waviness [27,28]. As-grown less-packed CNT arrays experience a larger local curvature and large reductions in effective modulus, while mechanically densified arrays are less curved and their stiffness is dominated by the low shear modulus of CNTs [28]. In respect to composite reinforcement, there have been several papers published from the early 2000s focused mostly on composites with low volume fractions (less than 25 vol%) of short discrete nanotubes [29][30][31] or nanofibres [32].…”

Section: Behavior In Tensionmentioning

confidence: 99%

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Aligned carbon nanotube–epoxy composites: the effect of nanotube organization on strength, stiffness, and toughness

2016

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A protocol has been developed for the production of epoxy-based composites containing high-volume fractions of aligned carbon nanotubes. The nanotubes were fabricated as continuous fibres or aligned mats directly from the CVD reactor, in which they were synthesized. The block composites with highly aligned and tightly packed nanotube assemblies were prepared via epoxy resin infiltration, and their volume fraction, distribution, and internal porosity being analysed prior to mechanical testing. The samples were tested in both axial tension and three-point bending. The results show that the strength and stiffness enhancements were close to pro rata with the volume fraction of the carbon nanotubes added. The failure modes were distinctly different from those characteristic of the conventional aligned carbon fibre composites. The fracture surface showed considerable evidence of pull-out of bundles of (*50) nanotubes, but the pull-out appeared to involve the resin matrix which drew out along with the bundles. Subsidiary cracks were bridged by nanotube bundles giving structures reminiscent of crazes in glassy polymers, what constitutes the distinct toughness mechanism and higher resistance to the transverse cracks propagation.

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Section: Behavior In Tensionmentioning

confidence: 99%

Section: Behavior In Tensionmentioning

confidence: 99%

Aligned carbon nanotube–epoxy composites: the effect of nanotube organization on strength, stiffness, and toughness

2016

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“…These oversimplifications of the CNT morphology lead to large over-predictions of the stiffness contribution of the CNTs to elastic modulus of the A-PNC, and a truly three-dimensional description of the CNT morphology that accounts the stochastic (random) nature of the CNT waviness (See Figure 1b for illustration) and the evolution of w with CNT packing proximity is necessary for more representative mechanical property prediction. 27 In this work, a previously reported simulation framework capable of simulating 10 5 CNTs with stochastic waviness, 27,31,60 and representative scaling of w with with V f , is used to evaluate the scaling of the intrinsic CNT elastic modulus (E cnt ) with w. 27,31 This is achieved by studying the contribution of (axial) stretching, (radial) shear, and bending on the deformation of CNTs in the A-PNC using an analysis similar to applied to study wavy CNTs, 31 which originates from early work on the mechanical behavior of carbon nanocoils. 61 In conjunction with recent experimental data on an exemplary A-PNC system, 26 these results are used to compare the predicted scaling of the A-PNC elastic modulusp (E pnc ) with V f for the current scheme with the results of a previous finite element analysis (FEA) to show that more complete descriptions of the CNT morphology can lead to more accurate material property prediction.…”

Section: Nomenclaturementioning

confidence: 99%

“…This report draws heavily from very recent studies on the mechanical behavior of wavy A-CNT (Ref. 31) and wavy CNT polymer composites (Ref. 27), to explore the mechanisms of CNT reinforcement in A-PNCs more in-depth.…”

Section: Nomenclaturementioning

confidence: 99%

“…[18][19][20][21][22][23][24][25][26][27][28] However, the properties reported by these previous works did not live up to the behavior predicted using current theoretical frameworks. 12 Some of the main reasons why existing models cannot accurately predict the behavior of A-CNTs architectures, such as A-CNT arrays, are the various CNT morphology and proximity effects, 13,14,18,29 which can strongly impact properties, 27,30,31 but are not well understood and cannot be adequately described in current-generation theoretical frameworks.…”

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confidence: 99%

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Influence of Waviness on the Elastic Properties of Aligned Carbon Nanotube Polymer Matrix Nanocomposites

Stein

Wardle

2016

57th AIAA/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference

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The promise of enhanced performance has motivated the study of one dimensional nanomaterials, especially aligned carbon nanotubes (A-CNTs), for the reinforcement of polymeric materials. While early work has shown that CNTs have remarkable theoretical properties, more recent work on aligned CNT polymer matrix nanocomposites (A-PNCs) have reported mechanical properties that are orders of magnitude lower than those predicted by rule of mixtures. This large difference primarily originates from the morphology of the CNTs that reinforce the A-PNCs, which have significant local curvature commonly referred to as waviness, but are commonly modeled using the oversimplified straight column geometry. Here we used a simulation framework capable of analyzing 10 5 wavy CNTs with realistic stochastic morphologies to study the influence of waviness on the compliance contribution of wavy A-CNTs to the effective elastic modulus of A-PNCs, and show that waviness is responsible for the orders of magnitude over-prediction of the A-PNC effective modulus by existing theoretical frameworks that both neglect the shear deformation mechanism and do not properly account for the CNT morphpology. Additional work to quantify the morphology of A-PNCs in three dimensions and simulate their full elastic constitutive relations is planned.

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Interface engineering of carbon fiber composites using CNT: A review

Sahu,

Ponnusami,

Weimer

et al. 2023

Polymer Composites

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This paper aims to explore the potential of carbon nanotubes (CNTs) in enhancing the structural capability and multifunctionality of carbon fiber composites in aerospace applications, primarily by focusing on interfacial applications. The conventional method of dispersing CNTs in a matrix is not fully efficient in exploiting the mechanical and multifunctional performance of CNTs. Hence, the use of CNTs at the interface or as a coating on the surface of carbon fibers has been suggested as a means of achieving multifunctionality, in addition to enhanced mechanical performance. The paper presents an overview of the various processes for growing CNTs on carbon fiber surfaces and examines the effects of CNT geometry and growth parameters on the properties of grafted fibers and their composites. Furthermore, it discusses the potential improvements in thermal and electrical conductivity achievable by incorporating CNTs at the interface, as well as the benefits of using CNTs as a sizing layer for carbon fibers, including enhanced fracture toughness and resistance to delamination.Highlights Comprehensive study of interface engineering in carbon fibers and Carbon Fibre Reinforced Plastic (CFRPs) using carbon nanotubes (CNTs). Improved transverse mechanical properties and overall thermal and electrical properties. Multifunctional applications possible with the use of CNT. Both experimental and numerical studies reviewed.

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Aligned carbon nanotube array stiffness from stochastic three-dimensional morphology

Cited by 45 publications

References 41 publications

Aligned carbon nanotube–epoxy composites: the effect of nanotube organization on strength, stiffness, and toughness

Aligned carbon nanotube–epoxy composites: the effect of nanotube organization on strength, stiffness, and toughness

Influence of Waviness on the Elastic Properties of Aligned Carbon Nanotube Polymer Matrix Nanocomposites

Interface engineering of carbon fiber composites using CNT: A review

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