Recovery of mechanical properties during annealing of deformed metals
has been modelled based on a microstructural representation comprising
two elements, (i) the cell/subgrain structure (size delta) and (ii) t
he dislocation density (rho) within the subgrains. These two microstru
ctural elements are treated as independent internal state variables, a
nd the recovery of flow stress obtained by adding the time dependent c
ontributions due to subgrain growth [sigma proportional to 1/delta(t)]
and dislocation network growth [sigma proportional to root rho(t)]. T
he growth of a dislocation network has been treated in terms of therma
lly activated glide, thermally activated cross-slip, climb and solute
drag as rate-controlling mechanisms. Subgrain growth has been analysed
in a manner analogous to normal grain growth, with climb of the bound
ary dislocations being the rate controlling mechanism. The model has s
uccessfully been applied in the interpretations of recovery observatio
ns in iron, aluminium and AlMg alloys. It follows from the theoretical
treatment as well as from the analysis of experimental data that the
characteristic logarithmic time dependence of low temperature recovery
is the result of a reaction controlled either by thermally activated
glide of jogged screw dislocations or by solute drag. It has been demo
nstrated that a mechanism based on thermally activated cross-slip does
not apply in this context.