Publications

Metallic materials in sliding contact typically undergo dislocation-mediated plasticity, which results in stick-slip frictional behavior associated with high coefficients of friction ({mu} > 0.8). Our recent work on two electroplated nanocrystalline Ni alloys reveal that under combined conditions of low stress and low sliding velocity, these metals have very low friction ({mu} < 0.3). The observed frictional behavior is consistent with the transition from dislocation-mediated plasticity to an alternative mechanism such as grain boundary sliding. Focused ion beam cross-sections viewed in the TEM reveal the formation of a subsurface tribological bilayer at the contact surface, where the parent nanocrystalline material has evolved in structure to accommodate the frictional contact. Grain growth at a critical distance below the contact surface appears to promote a shear-accomodation layer. We will discuss these results in the context of a grain-size dependent transition from conventional microcrystalline wear behavior to this unusual wear behavior in nanocrystalline FCC metals.

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The effect of local texture on inhomogeneous deformation is probed in strongly textured zirconium during compression. The use of in-situ digital image correlation at multiple length scales allows both qualitative and quantitative analysis of the relationship between grain orientation and patterns of deformation bands that form as the precursors to an adiabatic shear band. Experimental results indicate that basal textured zirconium does not deform homogenously at any of the length scales examined. ©2009 Society for Experimental Mechanics Inc.

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