Modelling the Evolution in Microchemistry and its Effects on the Softening Behavior of Cold Rolled AlFeMnSi-Alloys during Annealing

Emmanuel Hersent; Ke Huang; Jesper Friis; Knut Marthinsen

doi:10.4028/www.scientific.net/MSF.753.143

Paper Titles

Simulation of Grains Growing as Influenced by Triple Line Dragging
p.121

Disconnection Motion in Low- and High-Angle Symmetrical Tilt Grain Boundaries in HCP Metal
p.125

A New Approach to Solute Effect on Grain Boundary Migration
p.131

On the Generalisation of JMAK's Theory
p.137

Modelling the Evolution in Microchemistry and its Effects on the Softening Behavior of Cold Rolled AlFeMnSi-Alloys during Annealing
p.143

Modelling Time-Dependent Nucleation of Recrystallization in Aluminium Alloys
p.147

Modelling Dynamic Recrystallization in FCC Metals Employing Thermostatistics
p.153

Recrystallisation Characteristics of Cold Rolled Austenitic Stainless Steel during Repeated Annealing
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Ferrite Recrystallization in Cold-Rolled Dual Phase Steel
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HomeMaterials Science ForumMaterials Science Forum Vol. 753Modelling the Evolution in Microchemistry and its...

Modelling the Evolution in Microchemistry and its Effects on the Softening Behavior of Cold Rolled AlFeMnSi-Alloys during Annealing

Abstract:

A dedicated diffusion controlled precipitation model for AlMnFeSi-alloys, based on classical nucleation and growth theory, has been implemented and coupled to a phenomenological softening model accounting for the combined effect of recovery and recrystallization during annealing after cold rolling. The result is a fully coupled precipitation and softening model which in principle is capable of accounting for variations in solute levels and size and volume fraction of dispersoids and their interaction with the softening behavior during annealing.

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Materials Science Forum (Volume 753)

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143-146

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https://doi.org/10.4028/www.scientific.net/MSF.753.143

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Online since:

March 2013

Authors:

Emmanuel Hersent, Ke Huang, Jesper Friis, Knut Marthinsen

Keywords:

Concurrent Precipitation, Modeling, Precipitation, Recrystallization

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