abstract

• The synthesis of silver nanoparticles has been carried out in aqueous solutions in a stirred semibatch reactor through the reduction of silver ions (Ag ) by sulfite ions (SO32-), which were added at a tightly controlled rate up to a final sulfite/silver molar ratio of 0.45. Sodium dodecyl sulfate (SDS) was used as the stabilizer at concentrations below its critical micelle concentration. The effects of temperature, sulfite addition rate, and SDS concentration have been assessed.Ag turned to Ag 0 in 5 min or less only when the synthesis was performed at 97 °C and not below. The sulfite addition rates studied were 0.5, 7.5, 15, and 90 μmol/min. The size, shape, polydispersity, and stability of the nanoparticles were determined by the sulfite addition rate and SDS concentration. At low SDS concentration (4 mM), stable, spherical shape, small size nanoparticles were formed only at the two intermediate sulfite addition rates. At the highest sulfite addition rate, 9 nm mean size spherical nanoparticles having a low±5 nmpolydispersity were produced at a high SDS concentration of 10 mM. With the low SDS concentration, larger truncated and spherical shape nanoparticles were obtained. UV-Vis spectrophotometry and transmission electron microscopy were used to characterize the nanoparticles. © Springer Science Business Media B.V. 2012.
• The synthesis of silver nanoparticles has been carried out in aqueous solutions in a stirred semibatch reactor through the reduction of silver ions (Ag%2b) by sulfite ions (SO32-), which were added at a tightly controlled rate up to a final sulfite/silver molar ratio of 0.45. Sodium dodecyl sulfate (SDS) was used as the stabilizer at concentrations below its critical micelle concentration. The effects of temperature, sulfite addition rate, and SDS concentration have been assessed.Ag%2b turned to Ag 0 in 5 min or less only when the synthesis was performed at 97 °C and not below. The sulfite addition rates studied were 0.5, 7.5, 15, and 90 μmol/min. The size, shape, polydispersity, and stability of the nanoparticles were determined by the sulfite addition rate and SDS concentration. At low SDS concentration (4 mM), stable, spherical shape, small size nanoparticles were formed only at the two intermediate sulfite addition rates. At the highest sulfite addition rate, 9 nm mean size spherical nanoparticles having a low±5 nmpolydispersity were produced at a high SDS concentration of 10 mM. With the low SDS concentration, larger truncated and spherical shape nanoparticles were obtained. UV-Vis spectrophotometry and transmission electron microscopy were used to characterize the nanoparticles. © Springer Science%2bBusiness Media B.V. 2012.

authors

• Lopez-Miranda A.
• López Valdivieso Alejandro
• Viramontes-Gamboa G.

publication date

• 2012-01-01

funding provided via

• 132832, 79608  Grant

published in

• Journal of Nanoparticle Research  Journal

keywords

• Addition rate; Polydispersity; Silver nanoparticles; Size; Sodium dodecyl sulfate; Synthesis Sodium sulfite Batch reactors; Critical micelle concentration; High resolution transmission electron microscopy; Metal ions; Metal nanoparticles; Micelles; Molar ratio; Polydispersity; Silver nanoparticles; Sodium sulfite; Spheres; Sulfur compounds; Synthesis (chemical); Addition rate; Effects of temperature; Silver ions; Size; Spherical nanoparticles; Spherical shape; Stirred semibatch reactors; UV-vis spectrophotometry; Sodium dodecyl sulfate; dodecyl sulfate sodium; silver; silver nanoparticle; sulfite; aqueous solution; article; chemical reaction; concentration (parameters); particle size; priority journal; scanning electron microscopy; spectrophotometry; synthesis; temperature measurement; transmission electron microscopy; ultraviolet radiation

Digital Object Identifier (DOI)

• 10.1007/s11051-012-1101-4

start page

end page

volume

• 14

issue

• 9