Keynote: Modelling the quasi-static and high-strain rate deformation behaviour of magnesium alloy AZ31

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dc.contributor.authorProust, Gen_AU
dc.contributor.authorLi, Len_AU
dc.contributor.authorFlores-Johnson, EAen_AU
dc.contributor.authorShen, LMen_AU
dc.contributor.authorMuránsky, Oen_AU
dc.date.accessioned2023-01-27T01:02:36Zen_AU
dc.date.available2023-01-27T01:02:36Zen_AU
dc.date.issued2015-07-14en_AU
dc.date.statistics2022-12-12en_AU
dc.descriptionThe citation shows author E. A. Flores Johnson. This author generally publishes as Flores-Johnson (as shown in his ORCiD profile).en_AU
dc.description.abstractIn hexagonal close-packed (hcp) metals, plastic deformation is accommodated by different slip and twinning systems. Various factors affect the activation of the deformation mechanisms: alloy composition, grain size, temperature of deformation, strain rate and loading direction. The multiplicity of deformation mechanisms that can be activated and the dependence on loading conditions explain the observed asymmetry and anisotropy on the hardening behaviour and texture evolution. It is therefore important to be able to characterise these deformation mechanisms for specific loading conditions to gain a thorough understanding of the mechanical behaviour of hcp materials. Modern microscopy techniques, such as electron backscatter diffraction (EBSD), enable the quantitative analysis of twinning which is an important deformation mechanics for magnesium alloys. These characterisation techniques allow a better understanding of the way materials deform and provide valuable information for predicting their behaviour. For example using such techniques one can determine the different twinning modes that have contributed to deformation but also the volume fraction of material that has twinned. These microscopy techniques have enabled modellers to better understand the contribution of twinning in the hardening behaviour of the materials and to devise schemes to incorporate the effects of twinning on the hardening response or/and texture evolution of hcp materials. In this work we are investigating the deformation behaviour of magnesium alloys AZ31 under quasi-static and high-strain rate loading. The high-strain rate experiments were carried out using a Hopkinson bar and the microstructure of the deformed samples was measured using EBSD. The experimental results were used to calibrate and test the robustness of a strain-dependent visco-plastic self-consistent crystal plasticity model. © 2015 Scientechen_AU
dc.identifier.citationProust, G., Li, L., Flores Johnson, E. A., Shen, L. M., & Muransky, O. (2015). Keynote: Modelling the quasi-static and high-strain rate deformation behaviour of magnesium alloy AZ31. Keynote presentation to the 6th International Conference on Computational Methods (ICCM2015), Auckland, New Zealand, July 14–17 2015. Retrieved from: https://sci-en-tech.com/ICCM/index.php/ICCM2015/2015/paper/view/1202en_AU
dc.identifier.conferenceenddate17 July 2015en_AU
dc.identifier.conferencename6th International Conference on Computational Methods (ICCM2015en_AU
dc.identifier.conferenceplaceAuckland, New Zealanden_AU
dc.identifier.conferencestartdate14 July 2015en_AU
dc.identifier.urihttps://sci-en-tech.com/ICCM/index.php/ICCM2015/2015/paper/view/1202en_AU
dc.identifier.urihttps://apo.ansto.gov.au/dspace/handle/10238/14537en_AU
dc.language.isoenen_AU
dc.publisherScientechen_AU
dc.subjectSimulationen_AU
dc.subjectDeformationen_AU
dc.subjectAlloysen_AU
dc.subjectMagnesiumen_AU
dc.subjectCrystalsen_AU
dc.subjectPlasticityen_AU
dc.subjectStrain rateen_AU
dc.titleKeynote: Modelling the quasi-static and high-strain rate deformation behaviour of magnesium alloy AZ31en_AU
dc.typeConference Presentationen_AU
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