Correlations between morphology, crystal structure and magnetization of epitaxial cobalt-platinum films grown with pulsed laser ablation

The effects of growth rate (Gr), deposition temperature (Td), film thickness (tF ), and substrate induced strain (ǫ) on morphological, crystallographic and magnetic characteristics of equiatomic CoPt epitaxial films synthesized with pulsed laser deposition (PLD) are investigated. The (001) oriented single crystal substrates of MgO, SrTiO3 and LaAlO3 provide different degree of epitaxial strain for growth of the disordered face centered cubic (fcc) and ordered face centered tetragonal (L10) phases of CoPt. The films deposited at Td ≈ 600 C on all three substrates are fcc with in-plane magnetization and a narrow hysteresis loop of width ≈ 200 Oe. The L10 phase, stabilized only at Td ≥ 700 C becomes predominantly c-axis oriented as Td is increased to 800 C. While the crystallographic structure of the films depends solely on the Td, their microstructure and magnetization characteristics are decided by the growth rate. At the higher Gr (≈ 1 Å/sec) the L10 films have a maze-like structure which converts to a continuous film as the tF is increased from 20 nm to 50 nm. The magnetic coercivity of these films increases as the L10 phase fraction grows with Td and its orientation becomes out of the film plane. The evolution of microstructure with Td is remarkably different at lower growth rate (≈ 0.4 Å/sec). Here the structure changes from a self-similar fractal pattern to a disordered assembly of nano-dots as the Td is raised from