Theoretical model for yield strength of monocrystalline Ni3Al by simultaneously considering size and strain rate

Zhang, Z.W.; Cai, W.; Wang, J.; Yang, R.; Xiao, P.; Ke, F.J.; Lu, Chunsheng

doi:10.1016/S1003-6326(23)66148-5

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Access Status

Open access

Authors

Zhang, Z.W.

Cai, W.

Wang, J.

Yang, R.

Xiao, P.

Ke, F.J.

Lu, Chunsheng

Date

2023

Type

Journal Article

Metadata

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Citation

Zhang, Z.W. and Cai, W. and Wang, J. and Yang, R. and Xiao, P. and Ke, F.J. and Lu, C.S. 2023. Theoretical model for yield strength of monocrystalline Ni3Al by simultaneously considering size and strain rate. Transactions of Nonferrous Metals Society of China (English Edition). 33 (3): pp. 816-823.

Source Title

Transactions of Nonferrous Metals Society of China (English Edition)

DOI

10.1016/S1003-6326(23)66148-5

ISSN

1003-6326

Faculty

Faculty of Science and Engineering

School

School of Civil and Mechanical Engineering

Abstract

To comprehensively describe the size and strain rate dependent yield strength of monocrystalline ductile materials, a theoretical model was established based on the dislocation nucleation mechanism. Taking Ni3Al as an example, the model firstly fits results of molecular dynamics simulations to extract material dependent parameters. Then, a theoretical surface of yield strength is constructed, which is finally verified by available experimental data. The model is further checked by available third part molecular dynamics and experimental data of monocrystalline copper and gold. It is shown that this model can successfully leap over the huge spatial and temporal scale gaps between molecular dynamics and experimental conditions to get the reliable mechanical properties of monocrystalline Ni3Al, copper and gold.

Except where otherwise noted, this item's license is described as http://creativecommons.org/licenses/by-nc-nd/4.0/