Stress dependence of indentation modulus for carbon fiber in polymer composite

Stress dependence of indentation modulus for carbon fiber in polymer composite

Elastic modulus measured through atomic force microscopy (AFM)-based indentation on single carbon fiber (CF) is found with dependence on lateral applied stress. An in situ indentation experiment inside a high-resolution transmission electron microscope was performed to quantitatively understand this...

Full description

Bibliographic Details
Main Authors: Hongxin Wang, Han Zhang, Daiming Tang, Kenta Goto, Ikumu Watanabe, Hideaki Kitazawa, Masamichi Kawai, Hiroaki Mamiya, Daisuke Fujita
Format: Article
Language:English
Published: Taylor & Francis Group 2019-12-01
Series:Science and Technology of Advanced Materials
Subjects:
atomic force microscopy
indentation
Online Access:http://dx.doi.org/10.1080/14686996.2019.1600202
id doaj-88648aa136fc4983b65db39cf32136ad
record_format Article
spelling doaj-88648aa136fc4983b65db39cf32136ad2020-11-25T03:24:35ZengTaylor & Francis GroupScience and Technology of Advanced Materials1468-69961878-55142019-12-0120141242010.1080/14686996.2019.16002021600202Stress dependence of indentation modulus for carbon fiber in polymer compositeHongxin Wang0Han Zhang1Daiming Tang2Kenta Goto3Ikumu Watanabe4Hideaki Kitazawa5Masamichi Kawai6Hiroaki Mamiya7Daisuke Fujita8National Institute for Materials ScienceNational Institute for Materials ScienceNational Institute for Materials ScienceNational Institute for Materials ScienceNational Institute for Materials ScienceNational Institute for Materials ScienceUniversity of TsukubaNational Institute for Materials ScienceNational Institute for Materials ScienceElastic modulus measured through atomic force microscopy (AFM)-based indentation on single carbon fiber (CF) is found with dependence on lateral applied stress. An in situ indentation experiment inside a high-resolution transmission electron microscope was performed to quantitatively understand this phenomenon by observing microstructure change in the indented area. Change of graphitic basal plane misalignment angle during indentation was linked to a continuous change of modulus with the help of finite element simulation. The established relationship between modulus and indentation force was further used to calculate residual stress distribution in CF imbedded in a CF reinforced polymer composite using the AFM indentation technique. The stress-induced formation of nanoscale defects in the CF and their transformation into fracture were directly characterized.http://dx.doi.org/10.1080/14686996.2019.1600202atomic force microscopyindentation
collection DOAJ
language English
format Article
sources DOAJ
author Hongxin Wang
Han Zhang
Daiming Tang
Kenta Goto
Ikumu Watanabe
Hideaki Kitazawa
Masamichi Kawai
Hiroaki Mamiya
Daisuke Fujita
spellingShingle Hongxin Wang
Han Zhang
Daiming Tang
Kenta Goto
Ikumu Watanabe
Hideaki Kitazawa
Masamichi Kawai
Hiroaki Mamiya
Daisuke Fujita
Stress dependence of indentation modulus for carbon fiber in polymer composite
Science and Technology of Advanced Materials
atomic force microscopy
indentation
author_facet Hongxin Wang
Han Zhang
Daiming Tang
Kenta Goto
Ikumu Watanabe
Hideaki Kitazawa
Masamichi Kawai
Hiroaki Mamiya
Daisuke Fujita
author_sort Hongxin Wang
title Stress dependence of indentation modulus for carbon fiber in polymer composite
title_short Stress dependence of indentation modulus for carbon fiber in polymer composite
title_full Stress dependence of indentation modulus for carbon fiber in polymer composite
title_fullStr Stress dependence of indentation modulus for carbon fiber in polymer composite
title_full_unstemmed Stress dependence of indentation modulus for carbon fiber in polymer composite
title_sort stress dependence of indentation modulus for carbon fiber in polymer composite
publisher Taylor & Francis Group
series Science and Technology of Advanced Materials
issn 1468-6996
1878-5514
publishDate 2019-12-01
description Elastic modulus measured through atomic force microscopy (AFM)-based indentation on single carbon fiber (CF) is found with dependence on lateral applied stress. An in situ indentation experiment inside a high-resolution transmission electron microscope was performed to quantitatively understand this phenomenon by observing microstructure change in the indented area. Change of graphitic basal plane misalignment angle during indentation was linked to a continuous change of modulus with the help of finite element simulation. The established relationship between modulus and indentation force was further used to calculate residual stress distribution in CF imbedded in a CF reinforced polymer composite using the AFM indentation technique. The stress-induced formation of nanoscale defects in the CF and their transformation into fracture were directly characterized.
topic atomic force microscopy
indentation
url http://dx.doi.org/10.1080/14686996.2019.1600202
work_keys_str_mv AT hongxinwang stressdependenceofindentationmodulusforcarbonfiberinpolymercomposite
AT hanzhang stressdependenceofindentationmodulusforcarbonfiberinpolymercomposite
AT daimingtang stressdependenceofindentationmodulusforcarbonfiberinpolymercomposite
AT kentagoto stressdependenceofindentationmodulusforcarbonfiberinpolymercomposite
AT ikumuwatanabe stressdependenceofindentationmodulusforcarbonfiberinpolymercomposite
AT hideakikitazawa stressdependenceofindentationmodulusforcarbonfiberinpolymercomposite
AT masamichikawai stressdependenceofindentationmodulusforcarbonfiberinpolymercomposite
AT hiroakimamiya stressdependenceofindentationmodulusforcarbonfiberinpolymercomposite
AT daisukefujita stressdependenceofindentationmodulusforcarbonfiberinpolymercomposite
_version_ 1724601481174188032

Similar Items