Curtin University Homepage
  • Library
  • Help
    • Admin

    espace - Curtin’s institutional repository

    JavaScript is disabled for your browser. Some features of this site may not work without it.
    View Item 
    • espace Home
    • espace
    • Curtin Research Publications
    • View Item
    • espace Home
    • espace
    • Curtin Research Publications
    • View Item

    Quantitative characterization of the interfacial adhesion of Ni thin film on steel substrate: a compression-induced buckling delamination test

    Access Status
    Fulltext not available
    Authors
    Zhu, W.
    Zhou, Y.
    Guo, J.
    Yang, L.
    Lu, Chunsheng
    Date
    2015
    Type
    Journal Article
    
    Metadata
    Show full item record
    Citation
    Zhu, W. and Zhou, Y. and Guo, J. and Yang, L. and Lu, C. 2015. Quantitative characterization of the interfacial adhesion of Ni thin film on steel substrate: a compression-induced buckling delamination test. Journal of the Mechanics and Physics of Solids. 74: pp. 19-37.
    Source Title
    Journal of the Mechanics and Physics of Solids
    DOI
    10.1016/j.jmps.2014.09.012
    ISSN
    00225096
    School
    Department of Mechanical Engineering
    URI
    http://hdl.handle.net/20.500.11937/6563
    Collection
    • Curtin Research Publications
    Abstract

    A compression-induced buckling delamination test is employed to quantitatively characterize the interfacial adhesion of Ni thin film on steel substrate. It is shown that buckles initiate from edge flaws and surface morphologies exhibit symmetric, half-penny shapes. Taking the elastoplasticity of film and substrate into account, a three-dimensional finite element model for an edge flaw with the finite size is established to simulate the evolution of energy release rates and phase angles in the process of interfacial buckling-driven delamination. The results show that delamination propagates along both the straight side and curved front. The mode II delamination plays a dominant role in the process with a straight side whilst the curved front experiences almost the pure mode I. Based on the results of finite element analysis, a numerical model is developed to evaluate the interfacial energy release rate, which is in the range of 250–315 J/m2 with the corresponding phase angle from -41° to -66°. These results are in agreement with the available values determined by other testing methods, which confirms the effectiveness of the numerical model.

    Related items

    Showing items related by title, author, creator and subject.

    • Numerical study on interaction of surface cracking and interfacial delamination in thermal barrier coatings under tension
      Zhu, W.; Yang, L.; Guo, J.; Zhou, Y.; Lu, Chunsheng (2014)
      The interaction of surface cracking and interfacial delamination in thermal barrier coatings under tension is investigated by using a cohesive zone finite element model. It is found that the surface crack density has a ...
    • Finite element analysis of failure mechanisms of ceramic coatings on metallic parts for hydrogen storage applications
      Abedini, Sanam (2021)
      A coating system composed of a 316L stainless steel/Al2O3 functionally graded interlayer and a SiC top coat was considered for 316L stainless steel hydrogen storage containers due to promising properties of these coatings ...
    • Determination of interfacial adhesion energies of thermal barrier coatings by compression test combined with a cohesive zone finite element model
      Zhu, W.; Yang, L.; Guo, J.; Zhou, Y.; Lu, Chunsheng (2015)
      Determination of interfacial adhesion energies of thermal barrier coatings is important for understanding failure mechanisms and predicting their lifetime. Combined compression test with a cohesive zone finite element ...
    Advanced search

    Browse

    Communities & CollectionsIssue DateAuthorTitleSubjectDocument TypeThis CollectionIssue DateAuthorTitleSubjectDocument Type

    My Account

    Admin

    Statistics

    Most Popular ItemsStatistics by CountryMost Popular Authors

    Follow Curtin

    • 
    • 
    • 
    • 
    • 

    CRICOS Provider Code: 00301JABN: 99 143 842 569TEQSA: PRV12158

    Copyright | Disclaimer | Privacy statement | Accessibility

    Curtin would like to pay respect to the Aboriginal and Torres Strait Islander members of our community by acknowledging the traditional owners of the land on which the Perth campus is located, the Whadjuk people of the Nyungar Nation; and on our Kalgoorlie campus, the Wongutha people of the North-Eastern Goldfields.