• Title of article

    Indentation-induced localized deformation and elastic strain partitioning in composites at submicron length scale Original Research Article

  • Author/Authors

    R.I. Barabash، نويسنده , , H. Bei، نويسنده , , Y.F. Gao، نويسنده , , G.E. Ice، نويسنده ,

  • Issue Information
    دوهفته نامه با شماره پیاپی سال 2010
  • Pages
    6
  • From page
    6784
  • To page
    6789
  • Abstract
    Three-dimensional spatially resolved strains were mapped in a model NiAl/Mo composite after nanoindentation. The depth-dependent strain distributed in the two phases and partitioned across the composite interfaces is directly measured at submicron length scale using X-ray microdiffraction and compared with a detailed micromechanical stress analysis. It is shown that indentation-induced deformation in the composite material is distinct from deformation expected in a single-phase material. This difference arises in part from residual thermal strains in both phases of the composite in the as-grown state. Interplay between residual thermal strains and external mechanical strain results in a complex distribution of dilatational strain in the Mo fibers and NiAl matrix and is distinct in different locations within the indented area. Reversal of the strain sign (e.g., alternating tensile/compressive/tensile strain distribution) is observed in the NiAl matrix. Bending of the Mo fibers during indentation creates relatively large ∼1.5° misorientations between the different fibers and NiAl matrix. Compressive strain along the 〈0 0 1〉 direction reached −0.017 in the Mo fibers and −0.007 in the NiAl matrix.
  • Keywords
    Deformation , Micromechanics , Micro-/nanoindentation , X-ray synchrotron radiation , Composites
  • Journal title
    ACTA Materialia
  • Serial Year
    2010
  • Journal title
    ACTA Materialia
  • Record number

    1145262