The Temperature-Dependent Ideal Shear Strength of Solid Single Crystals

Tianbao Cheng; Daining Fang; Yazheng Yang

doi:10.1115/1.4038884

The Temperature-Dependent Ideal Shear Strength of Solid Single Crystals

Tianbao Cheng^*, Daining Fang, Yazheng Yang

^*Corresponding author for this work

Institute of Advanced Structure Technology

Beijing Institute of Technology

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

2 Citations (Scopus)

Abstract

Knowledge of the ideal shear strength of solid single crystals is of fundamental importance. However, it is very hard to determine this quantity at finite temperatures. In this work, a theoretical model for the temperature-dependent ideal shear strength of solid single crystals is established in the view of energy. To test the drawn model, the ideal shear properties of Al, Cu, and Ni single crystals are calculated and compared with that existing in the literature. The study shows that the ideal shear strength first remains approximately constant and then decreases almost linearly as temperature changes from absolute zero to melting point. As an example of application, the "brittleness parameter" of solids at elevated temperatures is quantitatively characterized for the first time.

Original language	English
Article number	031005
Journal	Journal of Applied Mechanics, Transactions ASME
Volume	85
Issue number	3
DOIs	https://doi.org/10.1115/1.4038884
Publication status	Published - 1 Mar 2018

Keywords

Ideal shear strength
brittleness parameter
high temperature
modeling
solid single crystal
unstable stacking fault energy

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10.1115/1.4038884

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abstract = "Knowledge of the ideal shear strength of solid single crystals is of fundamental importance. However, it is very hard to determine this quantity at finite temperatures. In this work, a theoretical model for the temperature-dependent ideal shear strength of solid single crystals is established in the view of energy. To test the drawn model, the ideal shear properties of Al, Cu, and Ni single crystals are calculated and compared with that existing in the literature. The study shows that the ideal shear strength first remains approximately constant and then decreases almost linearly as temperature changes from absolute zero to melting point. As an example of application, the {"}brittleness parameter{"} of solids at elevated temperatures is quantitatively characterized for the first time.",

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AU - Fang, Daining

AU - Yang, Yazheng

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N2 - Knowledge of the ideal shear strength of solid single crystals is of fundamental importance. However, it is very hard to determine this quantity at finite temperatures. In this work, a theoretical model for the temperature-dependent ideal shear strength of solid single crystals is established in the view of energy. To test the drawn model, the ideal shear properties of Al, Cu, and Ni single crystals are calculated and compared with that existing in the literature. The study shows that the ideal shear strength first remains approximately constant and then decreases almost linearly as temperature changes from absolute zero to melting point. As an example of application, the "brittleness parameter" of solids at elevated temperatures is quantitatively characterized for the first time.

AB - Knowledge of the ideal shear strength of solid single crystals is of fundamental importance. However, it is very hard to determine this quantity at finite temperatures. In this work, a theoretical model for the temperature-dependent ideal shear strength of solid single crystals is established in the view of energy. To test the drawn model, the ideal shear properties of Al, Cu, and Ni single crystals are calculated and compared with that existing in the literature. The study shows that the ideal shear strength first remains approximately constant and then decreases almost linearly as temperature changes from absolute zero to melting point. As an example of application, the "brittleness parameter" of solids at elevated temperatures is quantitatively characterized for the first time.

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KW - brittleness parameter

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KW - unstable stacking fault energy

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The Temperature-Dependent Ideal Shear Strength of Solid Single Crystals

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Keywords

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