# Fractal carbon nanotube fibers with mesoporous crystalline structure

**Authors:** H. Yue, V. Reguero, E. Senokos, A. Monreal-Bernal, B. Mas, J.P., Fern\'andez-Bl\'azquez, R. Marcilla, J. J. Vilatela

arXiv: 1902.04127 · 2019-02-13

## TL;DR

This paper investigates the hierarchical and fractal structure of macroscopic carbon nanotube fibers, revealing how their porosity and orientation influence mechanical properties and are characterized by advanced scattering techniques.

## Contribution

It provides new insights into the fractal and crystalline structure of CNT fibers and links their microstructure to mechanical performance improvements.

## Key findings

- Fractal dimension of fibers is 2.5 for MWCNT and 2.8 for SWCNT.
- Drawing increases fiber alignment and tensile strength.
- Crystallinity correlates with tensile properties.

## Abstract

Macroscopic fibres of carbon nanotubes are hierarchical structures combining long building blocks preferentially oriented along the fibre axis and a large porosity arising from the imperfect packing of bundles. Synchrotron small-angle X-ray scattering SAXS measurements show that such structure is a surface fractal with fractal dimension (Ds) of 2.5 for MWCNT fibres and 2.8 for SWCNT fibres. N2 adsorption measurements give similar values of 2.54 and 2.50, respectively. The fractal dimension and deviation from Porods law are related to density fluctuations associated with the wide distribution of separations between CNTs. These fluctuations are also evident as diffuse wide-angle X-ray scattering (WAXS) from CNTs at distances above turbostratic separation. The structure of CNT fibres produced at different draw ratios is compared in terms of degree of orientation and characteristic lengths parallel and perpendicular to the fibre. Drawing not only increases alignment but also the fraction of graphitic planes forming coherent domains capable of taking part in stress transfer by shear; thus increasing both tensile modulus and strength. The invariant-normalized intensity of the (002) equatorial reflection thus takes the form of a degree of crystallinity closely related to tensile properties.

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Source: https://tomesphere.com/paper/1902.04127