Naslov
Radiolytical synthesis and mechanism of gold nanoparticle formation

Autori
Jurkin, Tanja ; Gotić, Marijan ; Dražić, Goran

Vrsta, podvrsta i kategorija rada
Sažeci sa skupova, sažetak, znanstveni

Izvornik
ICARST 2017 : nternational Conference on Applications of Radiation Science and Technology (ICARST 2017) : Programme and Book of Abstracts / - Beč : International Atomic Energy Agency (IAEA), 2017, 376-376

Skup
International Conference on Applications of Radiation Science and Technology (ICARST 2017)

Mjesto i datum
Beč, Austrija, 24.04.2017. - 28.04.2017

Vrsta sudjelovanja
Poster

Vrsta recenzije
Međunarodna recenzija

Ključne riječi
gold nanoparticles ; gamma-irradiation ; microemulsion ; citrate ; alcohol oxidation

Sažetak
Gold nanoparticles (AuNPs) are widely used in analytical chemistry, in biomedicine, and catalysis. The reducing agent is very important parameter in the synthesis of AuNPs, however, the hypothesis of this study is that AuNPs could be synthesized without using reducing agents, i.e. that due to very low affinity of gold for oxygen AuNPs could be synthesized under highly oxidizing conditions. AuNPs were synthesized in a microemulsion water/TritonX-100/1-pentanol/cyclohexane using various reducing agents: (i) strong chemical reducing agent (NaBH4), (ii) γ-irradiation under moderately strong reducing/oxidizing conditions, and (iii) synthesis under highly oxidizing conditions (with addition of NaOH aqueous solution). All were performed at room temperature (RT). The size, size distribution, aggregation and stability of AuNPs in the microemulsions depend on the strength of reducing agent. When a strong chemical reducing agent NaBH4 was used AuNPs are not well-stabilized and are rather polydisperse ; gold crystallites 11.7 nm in size. Rather small and monodisperse AuNPs were obtained using γ-irradiation (30 kGy ; 8 kGy/h) ; stability depended on pH. γ-irradition was able to produce AuNPs in air-saturated microemulsions under highly oxidizing conditions. Smaller AuNPs were obtained by irradiation in the presence of N2 in comparison to the air (Figure 1). The γ-irradiation of nitrogen-saturated microemulsion at acidic pH produced AuNPs about 10 nm in size, which aggregated under isolation by centrifugation. The microemulsion stirred at RT and at pH<7 under oxidizing conditions did not produce AuNPs, while at pH>7 (stronger oxidizing conditions) well-dispersed 12 nm AuNPs were formed. Synthesis of AuNPs in 1-pentanol by adding NaOH aqueous solution at RT without using microemulsions and irradiation confirmed that oxidation of alcohols was responsible for AuNPs formation. Based on these findings we propose the base-catalyzed alcohol oxidation at RT as a new, simple and versatile synthesis route for obtaining gold nanoparticles. In order to further exploit the oxidation of organic molecules for AuNPs synthesis we studied the radiolytical synthesis of AuNPs in the presence of citrate. The γ-irradiation of Au(III)/citrate precursor solutions produced well-dispersed and highly concentrated gold colloids in the presence of dissolved oxygen, without adding any reducing or stabilizing agents. AuNP size can be controlled by saturating gases (air or nitrogen) present in the precursor solution. AuNPs synthesized in the presence of air (≈ 10 nm) were approximately two times larger than AuNPs synthesized in the presence of nitrogen (≈5 nm), as determined by UV-Vis spectroscopy. An easy radiolytical reduction of Au(III)/citrate precursor solution in the presence of dissolved oxygen could be explained by enhanced radiolytical oxidation/decarboxylation of citrate to dicarboxyacetone, acetone and other products. Thus, we confirmed that classical approach of using a reducing agent to synthesize AuNPs is not a determining factor, since diametrically different approach can be used, namely in stimulating the oxidation of organic molecules close to gold ions. However, the mechanism of oxidation of organic molecules during the synthesis is not clear and due to these reasons we introduced NMR spectroscopy in order to study the oxidation products of alcohol and citrate ions during the AuNPs synthesis.

Izvorni jezik
Engleski

Znanstvena područja
Kemija

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