Electron backscatter diffraction investigation of duplex-phase microstructure in a forged Zr-2.5Nb alloy

Microstructural features of a duplex-phase Zr-2.5Nb alloy were investigated in detail using electron channeling contrast(ECC)imaging and electron backscatter diffraction(EBSD)technique in an emission gun scanning electron microscope(FEGSEM).The excellent resolution provided by the FEGSEM promises the combined utilization of both techniques to be quite adequate for characterizing the duplex-phase microstructures.Results show that the microstructure of the Zr-2.5Nb alloy is composed of bulkαgrains(majority)in equiaxed or plate shape and thinβfilms(minority)surrounding the bulk grains,with their average grain size and thickness measured to be 1.4μm and 72 nm,respectively.Analyses onα-grain boundaries reveal a number of low angle boundaries,most of which belong to deformation-induced dislocation boundaries.Measurements on relative proportions of various Burgers boundaries suggest very weak(if any)variant selection duringβ→αcooling,which should be related to deformation-induced higher nucleation rate ofαphases.Compared to earlier attempts,more satisfactory indexing of fineβphases(down to nanoscale)is attained by the FEGSEM-based EBSD.Examples are presented to clearly reveal well-obeyed Burgers orientation relationships between adjacentαandβphases.Finally,it is deduced that continuing application of the FEGSEM-based EBSD to duplex-phase Zr alloys could help clarify controversies like the deformation priority of the two phases.