The influence of the ultrasound characteristics on the electrodeposition of copper from chloride-based electrolytes

The electrochemical deposition and dissolution of Cu from chloride-based electrolyte was studied employing the electrochemical quartz crystal microbalance (EQCM)-coupled ultrasound technique. The ultrasound was generated using an ultrasonic horn probe, which was positioned in the face-on configuration at a different distance (8, 15, and 22 mm) from the quartz. Small intensities of ultrasound (up to ca. 11-13 W cm & minus;2) caused a significant enhancement of anodic, cathodic currents, as well as the amount of deposited Cu paralleled by an increase in the current efficiencies due to the enhanced mass transport caused by ultrasound acoustic streaming. A further increase in the ultrasonic intensity continuously decreased the amount of Cu deposited as well as the calculated current efficiencies where the ultrasound acoustic cavitation (favor ablation) becomes more important and overtakes the effect of acoustic streaming. The peculiarities in sonoelectrochemistry at intermediate intensities (ca. 25 W cm & minus;2) could be explained by a competition between the two effects. In agreement with the literature, the Cu corrosion reaction is occurring in parallel to its anodic dissolution with a corrosion rate increasing with increasing the ultrasound intensity. At the horn-quartz distance of 8 mm and intensity of 76 W cm & minus;2 limits of the EQCM application (in the ultrasound field) were reached and the Cu deposition could not take place.

Automated summary

The study investigated the electrochemical deposition and dissolution of copper from a chloride-based electrolyte using electrochemical quartz crystal microbalance (EQCM) coupled with ultrasound. It found that low-intensity ultrasound significantly enhanced the anodic and cathodic currents as well as the amount of deposited copper due to enhanced mass transport, while high-intensity ultrasound led to a decrease in copper deposition and current efficiencies due to the dominance of acoustic cavitation over acoustic streaming. This demonstrates the competition between different ultrasound effects in sonoelectrochemistry.