Radiotracer diffusion studies of severely deformed, ultra-fine grained materials have revealed the presence of ultra-fast transport paths, which include "non-equilibrium" grain boundaries and free volume. Under some experimental conditions, percolating porosity is produced even in pure copper [Ribbe et al., Phys. Rev. Lett. 2009]. Micro-cracks may form in metals, if the local maximum shear stress exceeds the shear yield stress [Dieter GE. Mechanical metallurgy, McGraw-Hill, New York, 1986]. However, their growth and propagation is postponed till late in the deformation process because of the ductility of metals, the hydrostatic component of the stress system and/ or dynamic recovery/ recrystallization. That is, crack growth and propagation is present only when the scope for further deformation is highly restricted. Using this approach, the load required for equal channel angular pressing, the change in the slope of the Hall-Petch plot with decreasing grain size and the theoretical limit for the smallest grain size attainable in a metal in a SPD process are predicted and validated by experimental results. Experimentally successful prevention of percolated crack formation by the superposition of a hydrostatic pressure is also accounted for using this model.