Drops deposited on rough and hydrophobic surfaces can stay suspended with gas pockets underneath the liquid, then showing very low hydrodynamic resistance. When this superhydrophobic state breaks down, the subsequent wetting process can show differen
t dynamical properties. A suitable choice of the geometry can make the wetting front propagate in a stepwise manner leading to {it square-shaped} wetted area: the front propagation is slow and the patterned surface fills by rows through a {it zipping} mechanism. The multiple time scale scenario of this wetting process is experimentally characterized and compared to numerical simulations.
