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[资源] Ductile crystalline–amorphous nanolaminates

Ductile crystalline–amorphous nanolaminates
Yinmin Wang*†‡, Ju Li§, Alex V. Hamza*†, and Troy W. Barbee, Jr.†
*Nanoscale Synthesis and Characterization Laboratory, †Chemistry, Materials, and Life Sciences Directorate, Lawrence Livermore National Laboratory,
Livermore, CA 94550; and §Department of Materials Science and Engineering, Ohio State University, Columbus, OH 43210
Edited by William D. Nix, Stanford University, Stanford, CA, and approved May 25, 2007 (received for review March 14, 2007)
(美国科学院院刊)

It is known that the room-temperature plastic deformation of bulk metallic glasses is compromised by strain softening and shear localization, resulting in near-zero tensile ductility. The incorporation of metallic glasses into engineering materials, therefore, is
often accompanied by complete brittleness or an apparent loss of useful tensile ductility. Here we report the observation of an exceptional tensile ductility in crystalline copper/copper–zirconium glass nanolaminates. These nanocrystalline–amorphous nanolaminates exhibit a high flow stress of 1.09 0.02 GPa, a nearly
elastic-perfectly plastic behavior without necking, and a tensile elongation to failure of 13.8 1.7%, which is six to eight times higher than that typically observed in conventional crystalline– crystalline nanolaminates (<2%) and most other nanocrystalline materials. Transmission electron microscopy and atomistic simulations
demonstrate that shear banding instability no longer afflicts the 5- to 10-nm-thick nanolaminate glassy layers during tensile deformation, which also act as high-capacity sinks for dislocations, enabling absorption of free volume and free energy transported by the dislocations; the amorphous–crystal interfaces exhibit unique
inelastic shear (slip) transfer characteristics, fundamentally different from those of grain boundaries. Nanoscale metallic glass layers therefore may offer great benefits in engineering the plasticity of crystalline materials and opening new avenues for improving their strength and ductility.

metallic glass /size-dependent plasticity / nanocrystalline materials /amorphous–crystalline interface / tensile ductility

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