Strain rate induced amorphization in metallic nanowires

Hideyuki Ikeda; Yue Qi; Tahir Çagin; Konrad Samwer; William L. Johnson; William A. Goddard

doi:10.1103/PhysRevLett.82.2900

Strain rate induced amorphization in metallic nanowires

Hideyuki Ikeda
, Yue Qi
, Tahir Çagin
, Konrad Samwer
, William L. Johnson
, William A. Goddard

California Institute of Technology
Kagoshima National College of Technology
University of Augsburg

Research output: Contribution to journal › Article › peer-review

Abstract

Using molecular dynamics simulations with a many-body force field, we studied the deformation of single crystal Ni and NiCu random alloy nanowires subjected to uniform strain rates but kept at 300 K. For all strain rates, the Ni nanowire is elastic up to 7.5% strain with a yield stress of 5.5 GPa, far above that of bulk Ni. At high strain rates, we find that for both systems the crystalline phase transforms continuously to an amorphous phase, exhibiting a dramatic change in atomic short-range order and a near vanishing of the tetragonal shear elastic constant perpendicular to the tensile direction. This amorphization which occurs directly from the homogeneous, elastically deformed system with no chemical or structural inhomogeneities exhibits a new mode of amorphization.

Original language	English
Pages (from-to)	2900-2903
Number of pages	4
Journal	Physical Review Letters
Volume	82
Issue number	14
DOIs	https://doi.org/10.1103/PhysRevLett.82.2900
Publication status	Published - 1 Jan 1999
Externally published	Yes

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10.1103/PhysRevLett.82.2900

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title = "Strain rate induced amorphization in metallic nanowires",

abstract = "Using molecular dynamics simulations with a many-body force field, we studied the deformation of single crystal Ni and NiCu random alloy nanowires subjected to uniform strain rates but kept at 300 K. For all strain rates, the Ni nanowire is elastic up to 7.5\% strain with a yield stress of 5.5 GPa, far above that of bulk Ni. At high strain rates, we find that for both systems the crystalline phase transforms continuously to an amorphous phase, exhibiting a dramatic change in atomic short-range order and a near vanishing of the tetragonal shear elastic constant perpendicular to the tensile direction. This amorphization which occurs directly from the homogeneous, elastically deformed system with no chemical or structural inhomogeneities exhibits a new mode of amorphization.",

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AU - Ikeda, Hideyuki

AU - Qi, Yue

AU - Çagin, Tahir

AU - Samwer, Konrad

AU - Johnson, William L.

AU - Goddard, William A.

PY - 1999/1/1

Y1 - 1999/1/1

N2 - Using molecular dynamics simulations with a many-body force field, we studied the deformation of single crystal Ni and NiCu random alloy nanowires subjected to uniform strain rates but kept at 300 K. For all strain rates, the Ni nanowire is elastic up to 7.5% strain with a yield stress of 5.5 GPa, far above that of bulk Ni. At high strain rates, we find that for both systems the crystalline phase transforms continuously to an amorphous phase, exhibiting a dramatic change in atomic short-range order and a near vanishing of the tetragonal shear elastic constant perpendicular to the tensile direction. This amorphization which occurs directly from the homogeneous, elastically deformed system with no chemical or structural inhomogeneities exhibits a new mode of amorphization.

AB - Using molecular dynamics simulations with a many-body force field, we studied the deformation of single crystal Ni and NiCu random alloy nanowires subjected to uniform strain rates but kept at 300 K. For all strain rates, the Ni nanowire is elastic up to 7.5% strain with a yield stress of 5.5 GPa, far above that of bulk Ni. At high strain rates, we find that for both systems the crystalline phase transforms continuously to an amorphous phase, exhibiting a dramatic change in atomic short-range order and a near vanishing of the tetragonal shear elastic constant perpendicular to the tensile direction. This amorphization which occurs directly from the homogeneous, elastically deformed system with no chemical or structural inhomogeneities exhibits a new mode of amorphization.

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DO - 10.1103/PhysRevLett.82.2900

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EP - 2903

JO - Physical Review Letters

JF - Physical Review Letters

IS - 14

ER -

Strain rate induced amorphization in metallic nanowires

Abstract

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