Primary boron containing dispersoids grown from the melt in a Ti-45.5a
t.%Al-1.6at.%Fe-1.1at.%V-O.7at.%B alloy, and then annealed at 1473K, h
ave been investigated using optical microscopy, conventional transmiss
ion electron microscopy (CTEM) and analytical electron microscopy. The
dispersoid morphology is in the form of high aspect ratio plates, hun
dreds of microns across and cross-sectional widths of just a few hundr
ed nanometers, rather than a blocky or equiaxed morphology. These disp
ersoids are not monocrystalline, but have a layered structure parallel
to the plane of the plates. The dispersoids are distributed with rand
om orientations throughout the matrix and delineate the edges of lamel
lar domains, formed by the solid state transformation alpha--> gammaalpha(2)+ beta. Microchemical analysis by windowless energy dispersive
x-ray analysis (EDX) and serial electron energy loss spectroscopy (EE
LS) show that the chemical structure of these zones is in fact a mixtu
re of interleaved phases, rather than a single faulted boride crystal.
Boron mapping across the zones edge on to the plates and quantitative
EDX reveals boride plates down to a few nm wide have formed interleav
ed with ordered beta-phase (B2 CsCl structure). It is concluded that p
rimary borides and beta-phase simultaneously nucleate within the melt,
and the beta-phase is stabilized to room temperature by Fe and V segr
egation. Hence the borides can act as grain refiners by providing nucl
eation sites for beta-phase at high temperatures.