The effect of size and distribution of rod-shaped \beta' precipitates on the strength and ductility of a Mg-Zn alloy

TL;DR

This study systematically examines how the size and distribution of rod-shaped eta' precipitates affect the strength and ductility of a Mg-Zn alloy, revealing that smaller, more refined precipitates increase strength but reduce ductility.

Contribution

It is the first systematic investigation of how controlled deformation influences precipitate size distribution and mechanical properties in magnesium alloys.

Findings

Refined precipitates increased yield stress from 273 MPa to 309 MPa.

Yield stress correlates linearly with reciprocal interparticle spacing.

Precipitate refinement reduces ductility from 17% to 6%.

Abstract

We report on a quantitative investigation into the effect of size and distribution of rod-shaped \beta' precipitates on strength and ductility of a Mg-Zn alloy. Despite precipitation strengthening being crucial for the practical application of magnesium alloys this study represents the first systematic examination of the effect of controlled deformation on the precipitate size distribution and the resulting strength and ductility of a magnesium alloy. Pre-ageing deformation was used to obtain various distributions of rod-shaped \beta' precipitates through heterogeneous nucleation. Alloys were extruded to obtain a texture so as to avoid formation of twins and thus to ensure that dislocations were the primary nucleation site. Pre-ageing strain refined precipitate length and diameter, with average length reduced from 440 nm to 60 nm and diameter from 14 nm to 9 nm. Interparticle spacings were measured from micrographs and indicated some inhomogeneity in the precipitate distribution. The yield stress of the alloy increased from 273 MPa to 309 MPa. The yield stress increased linearly as a function of reciprocal interparticle spacing, but at a lower rate than predicted for Orowan strengthening. Pre-ageing deformation also resulted in a significant loss of ductility (from 17% to 6% elongation). Both true strain at failure and uniform elongation showed a linear relationship with particle spacing, in agreement with models for the accumulation of dislocations around non-deforming obstacles. Samples subjected to 3% pre-ageing deformation showed a substantially increased ageing response compared to non-deformed material; however, additional deformation (to 5% strain) resulted in only modest changes in precipitate distribution and mechanical properties.