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2 article(s) from Chang, Man-Ping

Bending and punching characteristics of aluminum sheets using the quasi-continuum method

Man-Ping Chang,
Shang-Jui Lin and
Te-Hua Fang

Beilstein J. Nanotechnol. 2022, 13, 1303–1315, doi:10.3762/bjnano.13.108

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Figure 1: The physical model of the nano-punching system. (a) The punch is made of nickel, and the workpiece ...

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Figure 2: The shear stress–displacement curves of O1, O2, and O3 orientations during the nano-punching proces...

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Figure 3: The schematic diagram of the nano-punching process. (a) The elastic deformation stage, (b) the plas...

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Figure 4: The atomic displacement vectors of O1, O2, and O3 during the punching process.

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Figure 5: The shear stress distribution diagram of orientation O1, O2, and O3 during the punching process. Th...

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Figure 6: The shear stress and strain distribution during the unloading process of the O1, O2, and O3 orienta...

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Figure 7: The shear stress–displacement curves of workpieces with various thicknesses during the nano-punchin...

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Figure 8: The fracture strength of the 5, 10, 15, and 20 Å workpieces.

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Figure 9: The shear stress distribution diagram of the 5, 10, 15, and 20 Å workpieces during the punching pro...

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Figure 10: The fracture strength of various workpiece clearances.

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Figure 11: The shear stress distribution diagram of the 15 Å workpiece with 5, 10, 15, and 20 Å clearance valu...

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Figure 12: The shear stress distribution diagram of the 20 Å workpiece with 5, 10, 15, and 20 Å clearance valu...

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Figure 13: The fracture strength of the punch with various angles.

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Figure 14: The shear stress distribution of θ = 5°, 10°, 15°, and 20° taper angles during the nano-punching pr...

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Full Research Paper

Published 10 Nov 2022

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Effects of temperature and repeat layer spacing on mechanical properties of graphene/polycrystalline copper nanolaminated composites under shear loading

Chia-Wei Huang,
Man-Ping Chang and
Te-Hua Fang

Beilstein J. Nanotechnol. 2021, 12, 863–877, doi:10.3762/bjnano.12.65

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Figure 1: Schematic of GPCuNL composite.

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Figure 2: Two different graphene chiralities and the bond length of graphene.

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Figure 3: Stress–strain curves of (a) zigzag and (b) armchair GPCuNL composites at different temperatures.

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Figure 4: The shear modulus of GPCuNL composites at different temperatures and with different graphene chiral...

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Figure 5: (a, c) Cross-sectional view of the CSP analysis of the GPCuNL composites and (b, d) DXA analysis of...

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Figure 6: (a–f) Von Mises stress of graphene under shear loading along the zigzag direction at 300 K. (a–c) T...

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Figure 7: (a, c) Cross-sectional view of the CSP analysis of the GPCuNL composites and (b, d) DXA analysis of...

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Figure 8: (a–f) Von Mises stress of graphene under shear loading along the armchair direction at 300 K. (a)–(...

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Figure 9: Out-of-plane displacement of graphene at different temperatures. (a1–a5) Zigzag graphene, (b1–b5) a...

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Figure 10: Stress–strain curves of zigzag graphene/Cu composites with different repeat layer spacings.

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Figure 11: The shear modulus of zigzag GPCuNL composites with different repeat layer spacings.

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Figure 12: The out-of-plane displacement of zigzag graphene with different repeat layer spacings.

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Figure 13: The DXA analysis of GPCuNL composites with different repeat layer spacings at 300 K. The magnified ...

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Figure 14: Stress–strain curves of zigzag GPCuNL composites with different grain sizes.

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Figure 15: Shear modulus of zigzag GPCuNL composites with different grain sizes.

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Figure 16: The structural evolution of polycrystalline Cu with different grain sizes. The “PD” symbols represe...

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Figure 17: The out-of-plane displacement of zigzag graphene in GPCuNL composites with different grain sizes.

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Full Research Paper

Published 12 Aug 2021

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