The surfaces of an iron-210 at. ppm sulfur alloy, Fe 7S 8 and FeS 2 cleaved in an ultra high vacuum were studied by Auger (AES) and electron energy loss Spectroscopy (EELS). The S LVV Auger transition for the intergranular fracture plane of the alloy indicates that the sulfur is bonded to the surface as though it were adsorbed. The loss energies of the transition from valence to conduction bands for the surface are identical to those for the transgranular fracture planes. The trans- and intergranular fracture planes have very similar fine structure in the Fe MVV Auger transition profile. This indicates that the interaction between iron and sulfur is too weak to perturb the electronic structure at the fracture surface. The spectral features of the electron transitions having kinetic energies between approximately 40 and 50 eV are explained by a normal Fe MVV Auger transition and an autoionization process after excitation of Fe 3 p electrons. The low spin ferrous ion in FeS 2 results in triplet peaks for the Fe MVV transition and doublet peaks for the autoionization event, but similar transitions for Fe 7S 8 exhibit singlet peak for each process.