Robust nanostructured silver and copper fabrics with localized surface plasmon resonance property for effective visible light induced reductive catalysis


Autoria(s): Anderson, Samuel R.; Mohammadtaheri, Mahsa; Kumar, Dipesh; O'Mullane, Anthony P.; Field, Matthew R.; Ramanathan, Rajesh; Bansal, Vipul
Data(s)

01/01/2016

Resumo

Inspired by high porosity, absorbency, wettability and hierarchical ordering on the micrometer and nanometer scale of cotton fabrics, a facile strategy is developed to coat visible light active metal nanostructures of copper and silver on cotton fabric substrates. The fabrication of nanostructured Ag and Cu onto interwoven threads of a cotton fabric by electroless deposition creates metal nanostructures that show a localized surface plasmon resonance (LSPR) effect. The micro/nanoscale hierarchical ordering of the cotton fabrics allows access to catalytically active sites to participate in heterogeneous catalysis with high efficiency. The ability of metals to absorb visible light through LSPR further enhances the catalytic reaction rates under photoexcitation conditions. Understanding the mode of electron transfer during visible light illumination in Ag@Cotton and Cu@Cotton through electrochemical measurements provides mechanistic evidence on the influence of light in promoting electron transfer during heterogeneous catalysis for the first time. The outcomes presented in this work will be helpful in designing new multifunctional fabrics with the ability to absorb visible light and thereby enhance light-activated catalytic processes.

Formato

application/pdf

Identificador

http://eprints.qut.edu.au/92292/

Publicador

John Wiley & Sons

Relação

http://eprints.qut.edu.au/92292/1/Robust%20metallised%20fabrics.pdf

DOI:10.1002/admi.201500632

Anderson, Samuel R., Mohammadtaheri, Mahsa, Kumar, Dipesh, O'Mullane, Anthony P., Field, Matthew R., Ramanathan, Rajesh, & Bansal, Vipul (2016) Robust nanostructured silver and copper fabrics with localized surface plasmon resonance property for effective visible light induced reductive catalysis. Advanced Materials Interfaces. (In Press)

Direitos

Copyright 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

Fonte

School of Chemistry, Physics & Mechanical Engineering; Science & Engineering Faculty

Palavras-Chave #030306 Synthesis of Materials #030603 Colloid and Surface Chemistry #030604 Electrochemistry #heterogeneous catalysis #multifunctional fabrics #surface plasmon resonance #Cu nanoparticles #Ag nanoparticles
Tipo

Journal Article