A numerical model designed to describe the microphysics of stratospheric ae
rosols along an isentropic trajectory is employed to study optical and phys
ical properties of mixed-phase polar stratospheric clouds (PSC). Particles
size distribution is studied following the evolution of 1000 size bins. Sol
id particles are assumed to first form upon homogeneous nucleation of water
ice. Heterogeneous formation of nitric acid trihydrate (NAT) and sulphuric
acid tetrahydrate (SAT) is then assumed to take place only on the homogene
ously nucleated ice particles. Two cooling rates, 10 K/day and 1000 K/day,
representative in turn of synoptic and wave cooling events are employed. Th
ese lead to the nucleation of 0.1% and 80% of ambient aerosols, respectivel
y. Following nucleation, the time evolution of PSC optical and physical pro
perties is shown to be strongly influenced by the number of nucleated parti
cles. The model-derived lidar backscatter ratio, depolarization ratio and e
xtinction (all at 532 nm), plus distribution surface area and effective rad
ius of equilibrium and non-equilibrium PSC are presented. These results pro
vide links between polarization lidar observations and PSC composition and
phase.