The mechanical response of core-shell structures for nanoporous metallic materials
N Abdolrahim and DF Bahr and B Revard and C Reilly and J Ye and TJ Balk and HM Zbib, PHILOSOPHICAL MAGAZINE, 93, 736-748 (2013).
DOI: 10.1080/14786435.2012.731528
Nanoporous gold (NP-Au) exhibits microscale plasticity, but macroscopically fails in a relatively brittle manner. This current study suggests that a core-shell structure can increase both ductility and strength of NP-Au. A core Au foam structure was created using conventional dealloying methods with average ligament size of 60nm. Nickel was then electroplated on to the NP-Au with layer thicknesses ranging from 2.5nm to 25nm. Nanoindentation demonstrated a significant increase in the hardness of the coated Np-Au, to about five times of that of the pure Np-Au, and a decrease in creep by increasing the thickness of the coated Ni layer. Molecular dynamics simulations of AuNi ligaments show the same trend of strengthening behavior with increasing Ni thickness suggesting that the strengthening mechanisms of the Np-Au are comparable to those for fcc nano ligaments. The simulations demonstrate two different strengthening mechanisms with the increased activity of the twins in plated AuNi ligaments, which leads to more ductile behavior, as opposing to the monolithic Au ligaments where nucleation of dislocations govern the plasticity during loading.
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