Abstract
•ZnO nanospheres and nanowires were grown using ultrasound and thermal activation techniques.•The growth uses forced hydrolysis of zinc acetate in diethylene glycol (DEG).•A thermochemical model was developed based on thermodynamic equilibrium calculations.•We estimate species distribution in the bubble in temperature range from 5000K to ambient.•We propose a new mechanism for ZnO growth assisted by ultrasound irradiation.
A fast and green approach is proposed for the preparation of nanocrystalline zinc oxide (ZnO) via ultrasonic (US) irradiation in polyol medium. The process uses forced hydrolysis of zinc acetate in diethylene glycol (DEG). The protocol is compared to thermal activation under the same chemical environment. The activation method is found to be playing a critical role in the selective synthesis of morphologically distinct nanostructures. As compared to thermally activated conventional polyol process, (US) permits to considerably reduce reaction time as well as size of particles. In addition, the shape of these nanoparticles was changed from long nanowires to small nanospheres, indicating different reaction mechanisms. To explain this difference, a thermochemical model was developed based on thermodynamic equilibrium calculations. The model estimate species distribution in the bubble in temperature range from 5000K to ambient simulating quenching process during bubble formation and collapse. Our results indicate the presence of high density of zinc atoms that could be responsible of a high density of nucleation as compared to thermal activation.