Litcius/Paper detail

Ascertaining the plastic deformation mechanisms of polycrystalline extruded Zn through in situ SEM/EBSD mechanical tests

A. Rezaei, Nafiseh Mollaei, Maral Sarebanzadeh, Biaobiao Yang, Seyed Mahmood Fatemi, Javier LLorca

2025International Journal of Plasticity9 citationsDOIOpen Access PDF

Abstract

• The sequence of plastic deformation mechanisms of polycrystalline Zn was reported by means of in situ mechanical tests in the SEM. • Plastic deformation was initially accommodated by <a> basal slip, leading to hardening, and grain boundary sliding. • Slip transfer at grain boundaries was never found because of grain boundary sliding. • <c+a> pyramidal II slip was also found but <c+a> pyramidal dislocations were dissociated into the basal plane and became sessile. • The contribution of twinning to the total strain was limited (around 11% when the applied strain was 16.7%). • •The strain hardening rate decreased sharply beyond 6.7% because of grain boundary slding and compression twinning The plastic deformation micro-mechanisms of extruded pure Zn deformed in tension along the extrusion direction were investigated by means of in situ scanning electron microscopy (SEM) integrated with electron back-scatter diffraction (EBSD). Plastic deformation began with the activation of < a > basal slip in grains with the highest Schmid factor while the incompatibility of deformation between neighbour grains was accommodated by grain boundary sliding. The geometrically necessary dislocation density increased sharply from 1.53 × 10 13 m⁻² to 9.03 × 10 13 m⁻² when applied strain reached 6.7%, and this increase coincides with the strong initial strain hardening region. The incompatibility of deformation between neighbour grains was accommodated by grain boundary sliding at strains above 3.3%, which somehow limited the strain hardening rate. Evidence of < c+a > pyramidal II slip was also found through slip trace analysis from the early stages of deformation, i.e. 1.6% strain, but it was always limited to a small fraction of suitably oriented grains. Moreover, transmission electron microscopy observations showed that many < c+a > pyramidal dislocations were dissociated into the basal plane and became sessile. {10 1 ¯ 2}<10 1 ¯ 1 ¯ > compression twins were nucleated at 3.3% strain and the fraction of grains undergoing twinning as well as the area fraction of twins increased proportionally to the applied strain. Twinning was favoured by the fiber texture and the twin variant with the highest Schmid factor was primarily activated in each grain. The contribution of twinning to the total strain was limited (around 11% when the applied strain was 16.7%). The strain hardening rate decreased sharply beyond 6.7% and the hardening contribution of basal slip was balanced by grain boundary slding and compression twinning. Finally, a high fraction of sub-grain boundaries that trigger recrystallization at larger strains ws found at 16.7%. These observations reveal the sequence and interaction of plastic deformation mechanisms in Zn, which may help design novel Zn alloys with improved mechanical properties.

Topics & Concepts

Materials scienceCrystal twinningSlip (aerodynamics)Grain boundaryPlasticityCrystalliteStrain hardening exponentComposite materialWork hardeningHardening (computing)Deformation mechanismMetallurgyGrain boundary strengtheningExtrusionDeformation (meteorology)CrystallographyDislocationElectron backscatter diffractionGrain sizeScanning electron microscopeStrain rateDislocation creepGrain Boundary SlidingPlane stressGrain boundary diffusion coefficientTransmission electron microscopySevere plastic deformationIn situMicrostructure and mechanical propertiesElectronic Packaging and Soldering TechnologiesNanomaterials and Printing Technologies