Study of the kinetics of cobalt electrodeposition in the presence of glycine

The electrochemical deposition, or electrodeposition, is a widely used technique to obtain metallic coatings. The presence of certain chemical species (additives) in plating baths can significantly influence the metal electrodeposition process. Glycine is an aminoacid present in many electrolytic solutions for electrodeposition of cobalt thin films and alloys, which are interesting due to their magnetic properties. The properties of some Co-based alloys obtained from glycine-containing baths are well documented, but studies of the exact role of the aminoacid are lacking. This Thesis presents studies attempting to understand the influence of glycine on the mechanisms of cobalt electrodeposition. In situ analysis techniques - external reflection FTIR spectroscopy and pH measurement near the electrochemical interface using indicator microelectrodes - were coupled to the electrochemical studies. Good-quality cobalt deposits were obtained from glycine-containing baths, and under higher overpotentials than possible over systems with no additive (in which precipitation of hydroxides occurs). Analysis of the cyclic voltammetry experiments indicated the electroactivity of cobalt-glycine complexes, and the slower reduction kinetics in comparison with glycine-free solutions at sufficiently high pH values. The kinetic studies were hindered by the parallel hydrogen evolution reaction and the existence of several chemical equilibria in solution. During cobalt electrodeposition from glycine-containing solutions, an expressive elevation of the near interface pH was observed. The spectroelectrochemical experiments also showed the displacement of cobalt complexation equilibria in solution, caused by the increase in the interfacial pH. All the conducted studies showed that the presence of glycine favors the hydrogen evolution reaction, decreasing the current efficiency for the electrodeposition process. Nevertheless, glycine was able to stabilize the electrolyte solution. (AU)