Effect of ultrasonic irradiation power on sonochemical synthesis of gold nanoparticles

Abstract In this work, optimized size distribution and optical properties in the colloidal synthesis of gold nanoparticles (GNPs) were obtained using a proposed ultrasonic irradiation assisted Turkevich-Frens method. The effect of three nominal ultrasound (20 kHz) irradiation powers: 60, 150, and 210 W have been analyzed as size and shape control parameters. The GNPs colloidal solutions were obtained from chloroauric acid (HAuCl4) and trisodium citrate (C6H5Na3O7 • 2H2O) under continuous irradiation for 1 hour without any additional heat or stirring. The surface plasmon resonance (SPR) was monitored in the UV-Vis spectra every 10 minutes to found the optimal time for localized SPR wavelength ( λ L S P R ), and the 210 sample procedure reduces the λ L S P R localization to 20 minutes, while 150 and 60 samples show λ L S P R in 60 minutes. The nucleation and growth of GNPs showed changes in shape and size distribution associated with physical (cavitation, temperature) and chemical (radical generation, pH) conditions in the aqueous solution. The results showed quasi−spherical GNPs as pentakis dodecahedron ( λ L S P R = 560 nm), triakis icosahedron ( λ L S P R = 535 nm), and tetrakis hexahedron ( λ L S P R = 525 nm) in a size range from 12-16 nm. Chemical effects of ultrasound irradiation were suggested in the disproportionation process, electrons of AuCl2− are rapidly exchanged through the gold surface. After AuCl4− and Cl− are desorbed, a complex tetrachloroaurate is recycled for the two-electron reduction by citrate, aurophilic interaction between complexes AuCl2−, electrons exchange, and gold seeds, the deposition of new gold atoms on the surface promoting the growth of GNPs. These mechanisms are enhanced by the effects of ultrasound, such as cavitation and transmitted energy into the solution. These results show that the plasmonic response from the reported GNPs can be tuned using a simple methodology with minimum infrastructure requirements. Moreover, the production method could be easily scalable to meet industrial manufacturing needs.