Towards in situ determination of 3D strain and reorientation in interpenetrating nanofibre composites

Research output: Contribution to journalArticleResearchpeer-review

Authors

  • Y. Zhang
  • P. De Falco
  • Y. Wang
  • E. Barbierie
  • N.J. Teririll
  • G. Falkenberg
  • N. M. Pugno
  • Himadri S. Gupta

Organisational units

External Organisational units

  • Photon Science, Deutsches Elektronen-Synchrotron DESY, Hamburg,
  • Queen Mary University of London, Institute of Bioengineering and School of Engineering and Material Science, London
  • Diamond Light Source, Harwell Science and Innovation Campus, Harwell
  • Laboratory of Bio-Inspired & Graphene Nanomechanics, Department of Civil, Environmental and Mechanical Engineering, University of Trento, Via Mesiano, 77, 38123 Trento
  • Ket Lab, Edoardo Amaldi Foundation, Italian Space Agency, Via del Politecnico snc, 00133 Rome

Abstract

Determining the in situ 3D nano- and microscale strain and reorientation fields in hierarchical nanocomposite materials is technically very challenging. Such a determination is important to understand the mechanisms enabling their functional optimization. An example of functional specialization to high dynamic mechanical resistance is the crustacean stomatopod cuticle. Here we develop a new 3D X-ray nanostrain reconstruction method combining analytical modelling of the diffraction signal, fibre-composite theory and in situ deformation, to determine the hitherto unknown nano- and microscale deformation mechanisms in stomatopod tergite cuticle. Stomatopod cuticle at the nanoscale consists of mineralized chitin fibres and calcified protein matrix, which form (at the microscale) plywood (Bouligand) layers with interpenetrating pore-canal fibres. We uncover anisotropic deformation patterns inside Bouligand lamellae, accompanied by load-induced fibre reorientation and pore-canal fibre compression. Lamination theory was used to decouple in-plane fibre reorientation from diffraction intensity changes induced by 3D lamellae tilting. Our method enables separation of deformation dynamics at multiple hierarchical levels, a critical consideration in the cooperative mechanics characteristic of biological and bioinspired materials. The nanostrain reconstruction technique is general, depending only on molecular-level fibre symmetry and can be applied to the in situ dynamics of advanced nanostructured materials with 3D hierarchical design.
Graphical abstract: Towards in situ determination of 3D strain and reorientation in the interpenetrating nanofibre networks of cuticle

Details

Original languageEnglish
Pages (from-to)11249-11260
Number of pages12
JournalNanoscale
Volume9.2017
Issue number31
DOIs
Publication statusPublished - 19 Jul 2017