Research Output per year
In order to enable exploitation of noble metal/poly(vinyl-‐alcohol) nanocomposites for device fabrication, solutions of poly(vinyl-‐alcohol) suitable for piezo-‐driven inkjet printing techniques are identified and discussed in terms of their material properties. The printable poly(vinyl-‐alcohol) medium is then exploited as a host material through the formation of silver or gold nanoparticles in order to create nanocomposites that exhibit a surface plasmon resonance behaviour associated with the small metallic inclusions. To mitigate some of the material redistribution effects associated with the drying of printed droplets containing finely divided materials, the metallic nanoparticles are formed after the printing and drying process is completed, by way of an in-‐situ reduction of an appropriate metal salt by the poly(vinyl-‐alcohol)-‐host matrix itself, which takes place at modest temperatures compatible with most substrate materials. An obvious application for such nanocomposites is in optical elements whereby the surface plasmon resonance associated with the metal is the functional aspect of devices such as sensors or active optical elements. High Resolution Transmission Electron Microscopy was used to examine the dimensions, distribution, morphology and crystal structure of the silver and gold nanoparticles in detail allowing discussion of their suitability for these applications and what further optimisation may be necessary to adequately control their formation.
|Date made available||2015|
|Publisher||University of Dundee|
Structural Characterisation of Printable Noble Metal/Poly(Vinyl-Alcohol) Nanocomposites for Optical ApplicationsHourd, A. C., Baker, R. T. & Abdolvand, A., 6 Aug 2015, In : Nanoscale. 7, 32, p. 13537-13546 10 p.
Research output: Contribution to journal › Article
Hourd, A. (Creator), Baker, R. (Contributor), Abdolvand, A. (Creator) (2015). Structural Characterisation of Printable Noble Metal/Poly(Vinyl-‐ Alcohol) Nanocomposites for Optical Applications. University of Dundee. Nanoscale_Paper_Data(.zip). 10.15132/10000102