Magnetooptical, optical, and magnetotransport properties of Co/Cu superlattices with ultrathin cobalt layers

Abstract

We investigated the field dependences of the magnetization and magnetoresistance of superlattices [Co(t x, A)/Cu(9.6 A)]30 prepared by magnetron sputtering, differing in the thickness of cobalt layers (0.3 A ≤ t Co ≤ 15 A). The optical and magnetooptical properties of these objects were studied by ellipsometry in the spectral region of hω= 0.09–6.2 eV and with the help of the transverse Kerr effect (hω= 0.5–6.2 eV). In the curves of an off-diagonal component of the tensor of the optical conductivity of superlattices with t Co = 3–15 A, a structure of oscillatory type (“loop”) was detected in the ultraviolet region, resulting from the exchange splitting of the 3d band in the energy spectrum of the face-centered cubic structure of cobalt (fcc Co). Based on magnetic experiments and measurements of the transverse Kerr effect, we found the presence of a superparamagnetic phase in Co/Cu superlattices with a thickness of the cobalt layers of 3 and 2 A. The transition from superlattices with solid ferromagnetic layers to superparamagnetic cluster-layered nanostructures and further to the structures based on Co and Cu (t Co = 0.3–1 A) with a Kondo-like characteristics of the electrical resistivity at low temperatures is analyzed.