Local strain quantification of a porous carbon fiber network material

R. N. Quammen, P. F. Rottmann

Research output: Contribution to journalArticlepeer-review

Abstract

While porous materials’ wide range of attractive functional properties have led to their development for a variety of applications, their intrinsically stochastic microstructures prevent straightforward approaches to predicting their mechanical behavior. This is attributed to the mechanisms that govern the macroscale behavior of these materials operating on multiple microstructure-specific length scales spanning several orders of magnitude. The goal of this work was to experimentally observe these operative deformation mechanisms to better improve the development of mechanism-informed models that more accurately predict the behavior of these materials. In this study compression tests were conducted on a porous carbon fiber network material. The resulting macroscale mechanical properties and mesoscale deformation behavior were tied together through digital image correlation (DIC) strain mapping. It was shown that deformation accumulation occurred via both reversible (fiber bending and sliding) and irreversible (fiber and junction failure) ways. The presence of irreversible deformation is indicated by strain being retained after unloading, with values of up to 0.426 locally and 0.248 globally. Local and macroscopic recovery of up to 0.306 and 0.207 strain respectively showcase the operation of reversible deformation. Furthermore, the calculation of energy loss coefficients increasing from 0.016 to 0.371 illustrates that the deformation occurs via dissipative mechanisms.

Original languageEnglish
Article numbere27990
JournalHeliyon
Volume10
Issue number6
DOIs
StatePublished - Mar 30 2024

Bibliographical note

Publisher Copyright:
© 2024 The Authors

Funding

This work was supported by NASA Kentucky Space Grant Consortium under NASA award 80NSSC20M0047. The authors would also like to acknowledge fruitful conversations with Catalin Picu, Matthew J. Beck, and Mujan N. Seif.

FundersFunder number
Kentucky Space Grant Consortium
National Aeronautics and Space Administration80NSSC20M0047

    Keywords

    • Carbon fiber
    • Compressive mechanical properties
    • Deformation behavior
    • Digital image correlation (DIC)
    • Fibrous network material

    ASJC Scopus subject areas

    • General

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