Deforming nanocrystalline nickel at ultrahigh strain rates

Y.M. WANG; E.M. BRINGA; J.M. MCNANEY; M. VICTORIA; A. CARO; A.M. HODGE; R. SMITH; B. TORRALBA; B.A. REMINGTON; C.A. SCHUH; H. JARMAKANI; M.A. MEYERS

APPLIED PHYSICS LETTERS

AMER INST PHYSICS

Lugar: American Institute of Physics; Año: 2006 vol. 88 p. 619171 - 619173

0003-6951

The deformation mechanism of nanocrystalline Ni (with grain sizes in the range of 30–100 nm) at ultrahigh strain rates (>107 s−1) was investigated. A laser-driven compression process was applied to achieve high pressures (20–70 GPa) on nanosecond timescales and thus induce high-strain-rate deformation in the nanocrystalline Ni. Postmortem transmission electron microscopy examinations revealed that the nanocrystalline structures survive the shock deformation, and that dislocation activity is a prevalent deformation mechanism for the grain sizes studied. No deformation twinning was observed even at stresses more than twice the threshold for twin formation in micron-sized polycrystals. These results agree qualitatively with molecular dynamics simulations and suggest that twinning is a difficult event in nanocrystalline Ni under shock-loading conditions.