Age hardening induced by the formation of (semi)-coherent precipitate phases
is crucial for the processing and final properties of the widely used Al-6000
alloys. Early stages of precipitation are particularly important from the
fundamental and technological side, but are still far from being fully
understood. Here, an analysis of the energetics of nanometric precipitates of
the meta-stable β′′ phases is performed, identifying the bulk, elastic
strain and interface energies that contribute to the stability of a nucleating
cluster. Results show that needle-shape precipitates are unstable to growth
even at the smallest size β′′ formula unit, i.e. there is no energy
barrier to growth. The small differences between different compositions points
toward the need for the study of possible precipitate/matrix interface
reconstruction. A classical semi-quantitative nucleation theory approach
including elastic strain energy captures the trends in precipitate energy
versus size and composition. This validates the use of mesoscale models to
assess stability and interactions of precipitates. Studies of smaller 3d
clusters also show stability relative to the solid solution state, indicating
that the early stages of precipitation may be diffusion-limited. Overall, these
results demonstrate the important interplay among composition-dependent bulk,
interface, and elastic strain energies in determining nanoscale precipitate
stability and growth
