2.5. Synthesis of triangular (pyram

2.5. Synthesis of triangular (pyramid) silver nanoparticles

A photochemical route was the first reliable and high yielding method for making solution-phase triangular Ag nanoprisms in which, the edge length can be controlled with excitation wavelength (Jin et al., 2001). Yamamoto et al., synthesized triangular silver nanoplates using the microwave promoted (MW) reduction of silver nitrate in aqueous solutions containing PVP (Yamamoto et al., 2004). Wiley et al., synthesized right bipyramids shaped silver nanoparticles using chemical polyol method, in which ethylene glycol (EG) was the solvent and reducing agent applying (NaBr) Br− (Wiley et al., 2006). Dong et al., 2010 could synthesize triangular silver nanoprisms using a stepwise reduction method in the absence of surfactant or special capping-agent. For this purpose, first small spherical silver nanoparticles were prepared by the rapid reduction of the precursor (silver nitrate) with NaBH4 (the strong reductant which, acted at the low temperature) at ice-bath temperature. The remaining precursor was further reduced by citrate (the weak reductant which, acted at the high temperature) under 70 °C to result in the formation of additional small spherical nanoparticles and induce the transformation of the spherical nanoparticles into the triangular nanoprisms. In this study it was found that the formation of the triangular nanoprisms is dependent on the molar ratios of two reductants (NaBH4 and trisodium citrate) used in the reactions. The residual silver ions after the formation of the spherical nanoparticles are necessary to promote their dissolution and transformation into the triangular nanoprisms. It can be said that, a balance between the precursor contributed to the formation of the small spherical particles and that to the transformation of the spherical nanoparticles is critical for the synthesis of the triangular nanoprisms (Dong et al., 2010). Kelly et al., synthesized the triangular-shaped silver nanoparticles. The used method was based on seed-mediated process involving reduction of silver ions by ascorbic acid in aqueous solution and also poly vinyl alcohol, citrate and polystyrenesulphonate as modifiers (Kelly et al., 2012). Millstone et al., reviewed a variety of solution-based methods like: Photochemical Syntheses and Thermal Syntheses (Chemical Reduction Methods), for synthesizing triangular Au and Ag triangular nanoprisms because of the mentioned reasons: (1) These structures have plasmonic features in the visible and IR regions, (2) they can be prepared in high yield and (3) can be readily functionalized with a variety of sulfur-containing adsorbates. They showed that in some cases, by adjusting experimental parameters, such as: metal ion and reducing agent ratios, surfactant concentrations, pH, irradiation wavelength, seed particle concentration and type, the dimensions of nanoprism can be controlled (Millstone et al., 2009).

Kai et al., could synthesize triangular silver nanoparticles by chemical reduction method. This was done via an appropriate method that was quick and easy. Finally, in order to observe and investigate silver nanoparticles, transmission electron microscopy and UV–visible spectrophotometer devices were used. Results showed that if silver nitrate, polyvinyl pyrrolidone and hydrazine hydrate were used as reagent, stabilizing factor and reducing agent, respectively, triangular silver nanoparticles with edge lengths in the size range of 50–200 nm were synthesized (Kai et al., 2012). Fig. 9 shows pyramid silver nanoparticles (Wiley et al., 2006).