Temperature-induced phase transitions of the ordered superlattice assembly of Au nanoclusters

TitleTemperature-induced phase transitions of the ordered superlattice assembly of Au nanoclusters
Publication TypeJournal Article
Year of Publication2005
AuthorsChaki, NK, Vijayamohanan, KP
JournalJournal of Physical Chemistry B
Volume109
Issue7
Pagination2552-2558
Date PublishedFEB
Type of ArticleArticle
ISSN1520-6106
Abstract

Superlattices of monolayer protected metallic and semiconducting nanoclusters have attracted significant attention due to their promising applications in nanotechnology. In this paper, we investigate the effect of temperature on the ordered superlattice structure of relatively larger sized An nanoclusters passivated with dodecanethiol [ca. Au-1415(RS)(328)] with the help of in situ temperature controlled X-ray diffraction (XRD) and infrared spectroscopy (IR) in conjunction with thermogravimetric (TG) and differential scanning calorimetric (DSC) analysis. In brief, monolayer protected Au nanoclusters (AuMPC) were prepared by a modified Brust synthesis technique, where dodecanethiol itself acts as both phase transfer and simultaneous capping agent during the reduction process, generating an average particle size of 3.72+/-0.4 nm after repeated solvent extraction and careful fractionation experiments. These particles are characterized with the help of UV-vis, transmission electron microscopic (TEM), IR, and NMR techniques, where effective capping as well as the superlattice formation on the TEM grid is evident from the combined analysis of these results. In situ low-angle XRD analysis shows that the particles undergo an irreversible phase transition in the temperature range of 100-115degreesC, which is also reflected in the data from in situ IR analysis. However, the DSC analysis does not account for this phase transition, although the reversible phase transition due to the alkyl chain dynamics is in good agreement with the previously reported results. These results indicate the formation of temperature-induced, diffusion-limited phase transition involving nonequilibrium fractal structures, which is in good agreement with the previous available theoretical studies. The determination of the temperature window for the stability of these ordered assemblies would be used to understand the effect of thermal stress for device applications.

DOI10.1021/jp045709x
Type of Journal (Indian or Foreign)

Foreign

Impact Factor (IF)3.187
Divison category: 
Physical and Materials Chemistry