Mesoscale evolution of non-graphitizing pyrolytic carbon in aligned carbon nanotube carbon matrix nanocomposites

Stein, Itai Y.; Kaiser, Ashley L.; Constable, Alexander J.; Acauan, Luiz; Wardle, Brian L.

doi:10.1007/s10853-017-1468-9

Cited by 23 publications

(19 citation statements)

References 91 publications

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“…Aligned CNT arrays were grown in a 22 mm internal diameter quartz tube furnace at atmospheric pressure via a previously described thermal catalytic chemical vapor deposition process with ethylene as the carbon source and 600 ppm of water vapor added to the inert gas. [40][41][42] The CNTs were grown on 1 cm Â 1 cm Si substrates via a base-growth mechanism on a catalytic layer composed of 1 nm Fe on 10 nm Al 2 O 3 deposited via electron beam physical vapor deposition. [43][44][45] The CNTs self-assemble into aligned arrays that were B10-300 mm tall, and were composed of multiwalled CNTs with an average outer diameter of B8 nm (3-7 walls with B5 nm inner diameter and intrinsic CNT density of E1.6 g cm À3 ), 42,[45][46][47] inter-CNT spacing of B60-80 nm, [48][49][50] and V f of B1% CNTs.…”

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confidence: 99%

Process-morphology scaling relations quantify self-organization in capillary densified nanofiber arrays

Kaiser

Stein

Cui

et al. 2018

Phys. Chem. Chem. Phys.

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confidence: 99%

Process-morphology scaling relations quantify self-organization in capillary densified nanofiber arrays

Kaiser

Stein

Cui

et al. 2018

Phys. Chem. Chem. Phys.

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“…Following substrate patterning, vertically-aligned CNT arrays were grown by a base-growth mechanism in a 22 mm internal diameter quartz tube furnace at atmospheric pressure via a previously-described thermal catalytic chemical vapor deposition process, which uses ethylene as the carbon source and 600 ppm of water vapor added to the inert gas, allowing cm-scale CNT arrays to be grown [71][72][73]. In each pattern, the growing CNTs self-assemble into aligned arrays of height (h) ∼ 10−50 μm, controlled by growth time and measured via optical microscopy.…”

Section: Substrate Patterning and Cnt Synthesismentioning

confidence: 99%

Morphology control of aligned carbon nanotube pins formed via patterned capillary densification

et al. 2019

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The exceptional intrinsic properties of aligned nanofibers, such as carbon nanotubes (CNTs), and their ability to be easily densified by capillary forces motivates their use as shape-engineerable materials. While a variety of self-assembled CNT structures, such as cell networks, micropillars, and pins have previously been fabricated via the capillary-mediated densification of patterned CNT arrays, predicting the critical pattern size (s cr) that separates cell versus pin formation and the corresponding process-morphology scaling relations within the micrometer range are outstanding. Here, facile and scalable mechanical patterning and capillary densification techniques are used to establish s cr by elucidating how the effective elastic modulus of aligned CNT arrays during densification governs the resulting pin geometries. Experiments and modeling show that this effective modulus scales with CNT height and is about an order of magnitude smaller for pins as compared to cell networks formed from bulk-scale (i.e. non-patterned) CNT arrays. Patterning therefore results in pins with a lower packing density (commensurate with double the wall thickness) and a larger characteristic length scale than bulk cell networks (i.e. s cr ∼ 5 × cell width). CNT arrays with the initial randomly-oriented carbon 'crust' removed via oxygen plasma etching yield a higher degree of structural uniformity and better agreement with the proposed elasto-capillary model, which enables the use of capillary densification to predictively design hierarchical and shapetunable materials for advanced thermal, electronic, and biomedical devices. RECEIVED

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“…Glassy carbon is not amorphous matter, but has a glass-like microcrystal structure, consisting of microcrystals of fullerene, carbon nanotube, and/or graphene [ 1 , 2 , 3 ]. In the microstructure of glassy carbon materials, the sp 2 carbon atoms are chemically bonded by sp 3 carbon atoms, forming a 3D structural network [ 4 , 5 , 6 , 7 , 8 , 9 ]. The possession of such a unique structure grants glassy carbon a great variety of physical and chemical properties [ 10 , 11 , 12 , 13 , 14 ].…”

Section: Introductionmentioning

confidence: 99%

“…Theoretical study on the structure of glassy carbon has also steadily progressed since its discovery. In recent years, the newly invented fullerene, carbon nanotube, and graphene helped researchers to restudy and re-evaluate the microstructures of glassy carbon [ 7 , 8 , 22 , 23 ]. Graphene, particularly, has obtained extended uses in drug delivery, membrane, biomedical and adsorption applications, in addition to use in sensors [ 24 , 25 , 26 , 27 , 28 ].…”

Section: Introductionmentioning

confidence: 99%

“…In a recent study, it was found that by adding a small fraction of carbon nanotubes to a phenol-formaldehyde polymer, similar glassy carbon could be achieved at 800 °C, 200 °C lower than the previous temperature [ 7 ]. Another study reported that compression of glassy carbon at high pressure and certain temperatures induced the local buckling of graphene sheets through sp 3 nodes to form interpenetrating graphene networks with a long-range disorder and short-range order on a nanometer scale [ 10 ].…”

Section: Introductionmentioning

confidence: 99%

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Fabrication and Characterization of Graphene Microcrystal Prepared from Lignin Refined from Sugarcane Bagasse

Tang

et al. 2018

Nanomaterials

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Graphene microcrystal (GMC) is a type of glassy carbon fabricated from lignin, in which the microcrystals of graphene are chemically bonded by sp3 carbon atoms, forming a glass-like microcrystal structure. The lignin is refined from sugarcane bagasse using an ethanol-based organosolv technique which is used for the fabrication of GMC by two technical schemes: The pyrolysis reaction of lignin in a tubular furnace at atmospheric pressure; and the hydrothermal carbonization (HTC) of lignin at lower temperature, followed by pyrolysis at higher temperature. The existence of graphene nanofragments in GMC is proven by Raman spectra and XRD patterns; the ratio of sp2 carbon atoms to sp3 carbon atoms is demonstrated by XPS spectra; and the microcrystal structure is observed in the high-resolution transmission electron microscope (HRTEM) images. Temperature and pressure have an important impact on the quality of GMC samples. With the elevation of temperature, the fraction of carbon increases, while the fraction of oxygen decreases, and the ratio of sp2 to sp3 carbon atoms increases. In contrast to the pyrolysis techniques, the HTC technique needs lower temperatures because of the high vapor pressure of water. In general, with the help of biorefinery, the biomass material, lignin, is found to be qualified and sustainable material for the manufacture of GMC. Lignin acts as a renewable substitute for the traditional raw materials of glassy carbon, copolymer resins of phenol formaldehyde, and furfuryl alcohol-phenol.

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Mesoscale evolution of non-graphitizing pyrolytic carbon in aligned carbon nanotube carbon matrix nanocomposites

Cited by 23 publications

References 91 publications

Process-morphology scaling relations quantify self-organization in capillary densified nanofiber arrays

Process-morphology scaling relations quantify self-organization in capillary densified nanofiber arrays

Morphology control of aligned carbon nanotube pins formed via patterned capillary densification

Fabrication and Characterization of Graphene Microcrystal Prepared from Lignin Refined from Sugarcane Bagasse

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