| The La1-xSrxMn1-yByO 3 perovskite systems where B represents a 3d transition metal such as Cr, Fe, Co, Ni, Cu, and Zn, are of significant interest due to their large magnetoresistance, and electronic transport properties that change significantly, depending on values of x and which transition metal used. Their applications in technology include cathodes for solid oxide fuel cells, resistance random access memory and catalysis. At certain doping concentrations on the B-site, metal-to-semiconductor or metal-to-insulator transitions coupled with colossal magnetoresistance occur, decreasing the resistivity (up to six orders of magnitude) upon the application of an external magnetic field. The Curie and Neel transition temperatures, TC and TN respectively, can be modified depending on the amount of transition metal substitution. In the parent system, La1-xSrxMn1-y3+Mnx 4+O3 at x = 0.4, the maximum transition temperature T CMax is reached in the La-based manganites.;To better understand the structural and magnetic properties of the 3d transition metal substituted perovskite La0.7Sr0.3Mn 0.7-x3+Mn0.34+Bx 3+O3, we studied the effects of replacing B with Cr and Ni atoms using x-ray and neutron diffraction and magnetic measurements. Of these two 3d transition metals, Cr has the least occupied outer valence shells, (Ar) 3d54s1 and has the same t 2g electronic configuration as Mn4+, while Ni has the most filled outer valence shells, (Ar) 3d4s2. The configurations of these outer valence electrons play a substantial role in the resultant magnetic interactions as witnessed by the unexpected magnetic ordering differences observed in the Cr and Ni-substituted systems. An extensive literature search indicated no previous neutron diffraction studies had been carried out for these two systems. |
