Developing stable fine-grain microstructures by large strain deformation

F. J. Humphreys; P. B. Prangnell; J. R. Bowen; A. Gholinia; C. Harris

doi:10.1098/rsta.1999.0395

Developing stable fine-grain microstructures by large strain deformation

F. J. Humphreys^*, P. B. Prangnell, J. R. Bowen, A. Gholinia, C. Harris

^*Corresponding author for this work

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

Abstract

Methods of deforming metals to large strains are reviewed and the process of equal channel angular extrusion is analysed in detail. The development of microstructure during large strain deformation is discussed, and it is concluded that the main criterion for the formation of a sub-micron grain structure is the generation of a sufficiently large fraction (greater than 0.7) of high-angle grain boundary during the deformation process. For aluminium alloys, it is found that a low-temperature anneal is required to convert the deformed microstructure into an equiaxed grain structure. The material, microstructural and processing factors that influence the formation of such fine-grain microstructures are discussed, and the stability of these microstructures at elevated temperatures is considered.

Original language	English
Pages (from-to)	1663-1681
Number of pages	19
Journal	Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences
Volume	357
Issue number	1756
DOIs	https://doi.org/10.1098/rsta.1999.0395
Publication status	Published - 1999

Keywords

Deformation
Grain boundary
Grains
Large strain
Sub-micron grain

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10.1098/rsta.1999.0395

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abstract = "Methods of deforming metals to large strains are reviewed and the process of equal channel angular extrusion is analysed in detail. The development of microstructure during large strain deformation is discussed, and it is concluded that the main criterion for the formation of a sub-micron grain structure is the generation of a sufficiently large fraction (greater than 0.7) of high-angle grain boundary during the deformation process. For aluminium alloys, it is found that a low-temperature anneal is required to convert the deformed microstructure into an equiaxed grain structure. The material, microstructural and processing factors that influence the formation of such fine-grain microstructures are discussed, and the stability of these microstructures at elevated temperatures is considered.",

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T1 - Developing stable fine-grain microstructures by large strain deformation

AU - Humphreys, F. J.

AU - Prangnell, P. B.

AU - Bowen, J. R.

AU - Gholinia, A.

AU - Harris, C.

PY - 1999

Y1 - 1999

N2 - Methods of deforming metals to large strains are reviewed and the process of equal channel angular extrusion is analysed in detail. The development of microstructure during large strain deformation is discussed, and it is concluded that the main criterion for the formation of a sub-micron grain structure is the generation of a sufficiently large fraction (greater than 0.7) of high-angle grain boundary during the deformation process. For aluminium alloys, it is found that a low-temperature anneal is required to convert the deformed microstructure into an equiaxed grain structure. The material, microstructural and processing factors that influence the formation of such fine-grain microstructures are discussed, and the stability of these microstructures at elevated temperatures is considered.

AB - Methods of deforming metals to large strains are reviewed and the process of equal channel angular extrusion is analysed in detail. The development of microstructure during large strain deformation is discussed, and it is concluded that the main criterion for the formation of a sub-micron grain structure is the generation of a sufficiently large fraction (greater than 0.7) of high-angle grain boundary during the deformation process. For aluminium alloys, it is found that a low-temperature anneal is required to convert the deformed microstructure into an equiaxed grain structure. The material, microstructural and processing factors that influence the formation of such fine-grain microstructures are discussed, and the stability of these microstructures at elevated temperatures is considered.

KW - Deformation

KW - Grain boundary

KW - Grains

KW - Large strain

KW - Sub-micron grain

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JO - Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences

JF - Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences

IS - 1756

ER -

Developing stable fine-grain microstructures by large strain deformation

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