Title of article
Non-linear finite element constitutive modeling of indentation into super- and ultrahard materials: The plastic deformation of the diamond tip and the ratio of hardness to tensile yield strength of super- and ultrahard nanocomposites
Author/Authors
Veprek-Heijman، نويسنده , , Maritza G.J. and Veprek، نويسنده , , Ratko G. and Argon، نويسنده , , Ali S. and Parks، نويسنده , , David M. and Veprek، نويسنده , , Stan، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2009
Pages
7
From page
3385
To page
3391
Abstract
Using a non-linear constitutive material model for super- (H ≥ 40 GPa) and ultrahard (H ≥ 80 GPa) materials that accounts for the pressure enhancement of elastic moduli and of plastic resistance, we present the effect of plastic deformation and resultant blunting of the diamond indenter, and discuss the limitations to the measurement on ultrahard materials by means of nano-indentation. We further show that the ratio of the hardness H to plastic resistance Y in tension amounts to about 2.4 for the super- and 2.84 for ultrahard nanocomposites, although the ratio of hardness to Youngʹs modulus is relatively high. These results are briefly discussed in terms of the expanding cavity model and the elastic–plastic transition.
Keywords
non-linear FEM , Indentation , H/Y ratio , Superhard materials , diamond , Plastic deformation
Journal title
Surface and Coatings Technology
Serial Year
2009
Journal title
Surface and Coatings Technology
Record number
1821179
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