A stack of thin, closely spaced conducting foils has been investigated by Lund et al. [Phys. Rev. ST Accel. Beams 16, 044202 (2013)] as a passive focusing lens for intense ion beams. The foils mitigate space-charge defocusing forces to enable the beam self-magnetic field to focus. In this study, we analyze possible degradation of focusing due to scattering of beam ions resulting from finite foil thickness using an envelope model and numerical simulations with the particle-in-cell code WARP. Ranges of kinetic energy where scattering effects are sufficient to destroy passive focusing are quantified. The scheme may be utilized to focus protons produced in intense laser-solid accelerator schemes. As an example, the spot size of an initially collimated 30 MeV proton beam with initial rms radius 200μm , perveance Q=1.8×10−2 , and initial transverse emittance ϵx,rms=0.87mmmrad propagating through a stack of 6.4μm thick foils, spaced 100μm apart, gives a 127.5μm spot with scattering and a 81.0μm spot without scattering, illustrating the importance of including scattering effects.