Dependence of Plastic Stability on 3D Interface Layer in Nanolaminated Materials

doi:10.1007/s40195-022-01425-3

Abstract

Abstract:

The nanolaminated materials generally exhibit poor plasticity due to the fast onset of shear instability. Engineering interface structure is an effective approach for enhancing plasticity via postponing or suppressing the shear instability. Here, we introduce 4 nm thick CuNb 3D amorphous interface layers and Nb 3D crystalline interface layers in Cu nanolaminated materials, respectively. In situ micro-pillar compression tests show that samples with crystalline interface layers exhibit shear instability, while the samples with amorphous interface layers display uniform deformation. Since the plastic deformation of the single-crystal crystalline interface layer is anisotropic, except for well-aligned slip systems, dislocations on other slip systems have a poor ability to transmit the 3D crystalline interface layer, leading to localized dislocations pileups and shear instability. In contrast, the amorphous interface layer which is plastically isotropic accommodates dislocations from arbitrary slip systems of the matrix, which can alleviate the stress concentrations at the interface, and thus suppresses the shear instability.

Key words: Multilayers, Interface, Plastic deformation, Dislocation, Amorphous interface

Shuimiao Jiang, Lichen Bai, Qi An, Zhe Yan, Weiming Li, Kaisheng Ming, Shijian Zheng. Dependence of Plastic Stability on 3D Interface Layer in Nanolaminated Materials[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(11): 1759-1764.

Figures/Tables 5

Fig. 1 a Cross-sectional bright-field TEM image of the sample with AIL, and the corresponding SAED pattern (inset), b HRTEM image of AIL, Fourier transform pattern shows the amorphous structure of AIL. c Cross-sectional bright-field TEM image of the sample with CIL and the corresponding SAED pattern (inset), d HRTEM image of CIL

Fig. 2 Mechanical response of the samples with AIL and CIL. a Engineering stress-strain curves of the samples with AIL and CIL. SEM images of the ϕ ~ 2 μm micropillars with AIL and CIL, before and after the uniaxial compression tests, micropillars with b1-b3 AIL, c1-c3 CIL

Fig. 3 Deformation mechanism of the sample with AIL and CIL. a Cross-sectional view of the pillar with AIL, b the enlarged image framed by the white line in a, with the SAED patterns (inset), c cross-sectional view of a pillar with CIL, and the shear band is marked by the white dashed line, d the enlarged image framed by the white line in c, with the SAED patterns of the shear band and matrix (inset)

Table 1 Parameters of slip systems in Fig. 4a

	Cu (-1-11) [101] Nb (01-1) [111]	Cu (-1-11) [101] Nb (101) [111]
ψ^αβ	35°	90°
θ^αβ	0°	0°
m_α-load direction [110]	0.41	0.41
m_β-load direction [111]	0.27	0.27
Dislocation transmissibility	Yes	No

Fig. 4 Schematic diagram of the deformation process for samples with AIL and CIL. Schematic diagrams of the a CIL and d AIL. Illustration of the dislocation-interface interaction of b, c CIL and e, f AIL

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