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Effects of rolling reduction on Burgers orientation relationship and slip behavior of a Ti–5.5Mo–7.2Al–4.5Zr–2.6Sn–2.1Cr alloy

Duoduo Wang, Qunbo Fan, Lin Yang, Haichao Gong, Jingjiu Yuan, Kai Chen, Xinjie Zhu, Xingwang Cheng, Zhiming Zhou

2021Journal of Materials Research and Technology23 citationsDOIOpen Access PDF

Abstract

The important but highly complex α/β Burgers orientation relationship and slip behavior of a Ti–5.5Mo–7.2Al–4.5Zr–2.6Sn–2.1Cr titanium alloy plate were obtained and elaborated, which was subjected to hot rolling with 20%, 40%, and 60% reductions in thickness. The electron backscatter diffraction statistical results showed that the Burgers orientation relationship was strictly maintained in the initial microstructure and exhibited a slight deviation of ∼10° at 20% reduction. With the thickness reduction increasing to 40% and 60%, this classical relation between α- and β-Ti will be gradually broken. Furthermore, the low-angle grain boundaries fractions of the β phase were 94.95% and 92.77% at 20% and 40% reductions, respectively, indicating that the β phase had a significant contribution to the overall plastic deformation. For the α phase, the relative frequencies of the <112¯0>{0001}α and <112¯0>{101¯0}α slip systems were 32.81% and 44.43% at 20% reduction, respectively. Noticeably, under the applied loading of normal direction, the <112¯0>{0001}α slip system became more pronounced at 60% reduction (i.e., 59.01%) and, hence promoted a considerable strain partitioning in the α phase. In terms of typical α grains, an obvious intragranular misorientation diversity at 60% reduction was further traced, thereby reasonably leading to the Schmid factor gradient within grain interior and the breakdown of Burgers orientation relationship.

Topics & Concepts

Materials scienceMisorientationSlip (aerodynamics)Electron backscatter diffractionAlloyMicrostructureDiffractionGrain boundaryLattice (music)Composite materialCondensed matter physicsThermodynamicsOpticsPhysicsAcousticsTitanium Alloys Microstructure and PropertiesMetal and Thin Film MechanicsIntermetallics and Advanced Alloy Properties