A short review on high strain rate superplasticity in magnesium-based composites materials

Abdul Malik; Yangwei Wang

doi:10.1016/j.ijlmm.2022.10.004

A short review on high strain rate superplasticity in magnesium-based composites materials

Abdul Malik^*, Yangwei Wang^*

^*Corresponding author for this work

School of Material Science and Engineering

Dongguan University of Technology

Research output: Contribution to journal › Review article › peer-review

7 Citations (Scopus)

Abstract

Magnesium composites are next-generation lightweight materials for aerospace and military industries. However, the complex shape components of magnesium composites cannot be designed at ambient temperature, therefore, they need to be processed at elevated temperatures. Generally, material at elevated temperatures displays superplasticity. It is more interesting that magnesium composites exhibite high strain rate superplasticity compared to aluminum alloys. Therefore, this review article sheds light on the superplastic deformation behavior of magnesium composites fabricated by different routes. Further, the stress-energy, cavitation nucleation and its impact on the elongation to fracture have been explored. At the end of the review article, some terrifying unresolved subjects have been addressed, so that their potential use can be enhanced as complex shape components.

Original language	English
Pages (from-to)	214-224
Number of pages	11
Journal	International Journal of Lightweight Materials and Manufacture
Volume	6
Issue number	2
DOIs	https://doi.org/10.1016/j.ijlmm.2022.10.004
Publication status	Published - Jun 2023

Keywords

Cavitation
Elongation to fracture
HSRS
Mg composites
Thermomechanical processing

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10.1016/j.ijlmm.2022.10.004

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title = "A short review on high strain rate superplasticity in magnesium-based composites materials",

abstract = "Magnesium composites are next-generation lightweight materials for aerospace and military industries. However, the complex shape components of magnesium composites cannot be designed at ambient temperature, therefore, they need to be processed at elevated temperatures. Generally, material at elevated temperatures displays superplasticity. It is more interesting that magnesium composites exhibite high strain rate superplasticity compared to aluminum alloys. Therefore, this review article sheds light on the superplastic deformation behavior of magnesium composites fabricated by different routes. Further, the stress-energy, cavitation nucleation and its impact on the elongation to fracture have been explored. At the end of the review article, some terrifying unresolved subjects have been addressed, so that their potential use can be enhanced as complex shape components.",

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author = "Abdul Malik and Yangwei Wang",

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AU - Malik, Abdul

AU - Wang, Yangwei

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N2 - Magnesium composites are next-generation lightweight materials for aerospace and military industries. However, the complex shape components of magnesium composites cannot be designed at ambient temperature, therefore, they need to be processed at elevated temperatures. Generally, material at elevated temperatures displays superplasticity. It is more interesting that magnesium composites exhibite high strain rate superplasticity compared to aluminum alloys. Therefore, this review article sheds light on the superplastic deformation behavior of magnesium composites fabricated by different routes. Further, the stress-energy, cavitation nucleation and its impact on the elongation to fracture have been explored. At the end of the review article, some terrifying unresolved subjects have been addressed, so that their potential use can be enhanced as complex shape components.

AB - Magnesium composites are next-generation lightweight materials for aerospace and military industries. However, the complex shape components of magnesium composites cannot be designed at ambient temperature, therefore, they need to be processed at elevated temperatures. Generally, material at elevated temperatures displays superplasticity. It is more interesting that magnesium composites exhibite high strain rate superplasticity compared to aluminum alloys. Therefore, this review article sheds light on the superplastic deformation behavior of magnesium composites fabricated by different routes. Further, the stress-energy, cavitation nucleation and its impact on the elongation to fracture have been explored. At the end of the review article, some terrifying unresolved subjects have been addressed, so that their potential use can be enhanced as complex shape components.

KW - Cavitation

KW - Elongation to fracture

KW - HSRS

KW - Mg composites

KW - Thermomechanical processing

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SN - 2588-8404

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JO - International Journal of Lightweight Materials and Manufacture

JF - International Journal of Lightweight Materials and Manufacture

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A short review on high strain rate superplasticity in magnesium-based composites materials

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Keywords

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