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 … Show more

“…The structural transformation takes place in nanoscale metallic wires under uniaxial strain [12,14,[17][18]23]. At lower strain rates, the Ni nanowire shows superplasticity [12,13], and at sufficiently high strain rates, it can transform continuously to an amorphous metal at constant temperature [13,14,23]. The Au nanowires, before breaking under tensile stress, can get as thin as one-atom chains, and as long as five suspended atoms [18,21].…”

“…It should be emphasized that the loading process of the tensile strain is different from those described in Refs. [13,14], where the tensile strain with increments of 0.5% in its total length after some time steps. In the present work, the tensile strain is increased by 5 Â 10 À6 , 2 Â 10 À6 , 5 Â 10 À7 in each time step along the Z-direction for the strain rate of 0.25%/ps, 0.1%/ps, and 0.025%/ps, respectively.…”

“…In the present paper, MD simulations have been performed with the quantum corrected SuttenChen (Q-SC) type many-body force field modified by Kimura et al [24] in which the parameters were optimized to describe the lattice parameter, cohesive energy, bulk modulus, elastic constants, phonon dispersion, vacancy formation energy, and surface energy, leading to an accurate description of many properties of metals and their alloys [25][26][27]. We have simulated the tensile process of Ni nanowire at room temperature.…”

“…However, measuring the mechanical and electrical properties of a nanowire is a difficult task due to the small dimensions [11]. In recent years, the deformation of nanowires have been studied by molecular dynamics simulations using either embodied-atom-method (EAM) [12][13][14][15] or effective-medium theory (EMT) [16,17] potentials as well as first-principles method based on the density functional theory (DFT) [18][19][20][21]. These studies focus on the correlation of the force (associated with the changes in the bonding of the nanowire) and the conductance for the metallic Au, Ni, and Na nano-contacts [17,22] and Au, Ni, Al, Na, and SiSe 2 nanowire [12,16,20,23].…”

“…These studies focus on the correlation of the force (associated with the changes in the bonding of the nanowire) and the conductance for the metallic Au, Ni, and Na nano-contacts [17,22] and Au, Ni, Al, Na, and SiSe 2 nanowire [12,16,20,23]. The structural transformation takes place in nanoscale metallic wires under uniaxial strain [12,14,[17][18]23]. At lower strain rates, the Ni nanowire shows superplasticity [12,13], and at sufficiently high strain rates, it can transform continuously to an amorphous metal at constant temperature [13,14,23].…”

The uniaxial tensile deformation of Ni nanowire: atomic-scale computer simulations

“…The structural transformation takes place in nanoscale metallic wires under uniaxial strain [12,14,[17][18]23]. At lower strain rates, the Ni nanowire shows superplasticity [12,13], and at sufficiently high strain rates, it can transform continuously to an amorphous metal at constant temperature [13,14,23]. The Au nanowires, before breaking under tensile stress, can get as thin as one-atom chains, and as long as five suspended atoms [18,21].…”

“…It should be emphasized that the loading process of the tensile strain is different from those described in Refs. [13,14], where the tensile strain with increments of 0.5% in its total length after some time steps. In the present work, the tensile strain is increased by 5 Â 10 À6 , 2 Â 10 À6 , 5 Â 10 À7 in each time step along the Z-direction for the strain rate of 0.25%/ps, 0.1%/ps, and 0.025%/ps, respectively.…”

“…In the present paper, MD simulations have been performed with the quantum corrected SuttenChen (Q-SC) type many-body force field modified by Kimura et al [24] in which the parameters were optimized to describe the lattice parameter, cohesive energy, bulk modulus, elastic constants, phonon dispersion, vacancy formation energy, and surface energy, leading to an accurate description of many properties of metals and their alloys [25][26][27]. We have simulated the tensile process of Ni nanowire at room temperature.…”

“…However, measuring the mechanical and electrical properties of a nanowire is a difficult task due to the small dimensions [11]. In recent years, the deformation of nanowires have been studied by molecular dynamics simulations using either embodied-atom-method (EAM) [12][13][14][15] or effective-medium theory (EMT) [16,17] potentials as well as first-principles method based on the density functional theory (DFT) [18][19][20][21]. These studies focus on the correlation of the force (associated with the changes in the bonding of the nanowire) and the conductance for the metallic Au, Ni, and Na nano-contacts [17,22] and Au, Ni, Al, Na, and SiSe 2 nanowire [12,16,20,23].…”

“…These studies focus on the correlation of the force (associated with the changes in the bonding of the nanowire) and the conductance for the metallic Au, Ni, and Na nano-contacts [17,22] and Au, Ni, Al, Na, and SiSe 2 nanowire [12,16,20,23]. The structural transformation takes place in nanoscale metallic wires under uniaxial strain [12,14,[17][18]23]. At lower strain rates, the Ni nanowire shows superplasticity [12,13], and at sufficiently high strain rates, it can transform continuously to an amorphous metal at constant temperature [13,14,23].…”

The uniaxial tensile deformation of Ni nanowire: atomic-scale computer simulations

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