Nanomechanics of Individual Aerographite Tetrapods

Overview

Journal Nat Commun

Specialty Biology

Date 2017 Apr 13

PMID 28401930

Citations 6

Authors

Raimonds Meija

Stefano Signetti

Arnim Schuchardt

Kerstin Meurisch

Daria Smazna

Matthias Mecklenburg

Karl Schulte

Donats Erts

Oleg Lupan

Bodo Fiedler

Yogendra Kumar Mishra

Rainer Adelung

Nicola M Pugno

Affiliations

Soon will be listed here.

Abstract

Carbon-based three-dimensional aerographite networks, built from interconnected hollow tubular tetrapods of multilayer graphene, are ultra-lightweight materials recently discovered and ideal for advanced multifunctional applications. In order to predict the bulk mechanical behaviour of networks it is very important to understand the mechanics of their individual building blocks. Here we characterize the mechanical response of single aerographite tetrapods via in situ scanning electron and atomic force microscopy measurements. To understand the acquired results, which show that the overall behaviour of the tetrapod is governed by the buckling of the central joint, a mechanical nonlinear model was developed, introducing the concept of the buckling hinge. Finite element method simulations elucidate the governing buckling phenomena. The results are then generalized for tetrapods of different size-scales and shapes. These basic findings will permit better understanding of the mechanical response of the related networks and the design of similar aerogels based on graphene and other two-dimensional materials.

Citing Articles

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