| Literature DB >> 26278239 |
Francesco Floris1, Cristiana Figus2, Lucia Fornasari1, Maddalena Patrini1, Paola Pellacani3, Gerardo Marchesini3, Andrea Valsesia3, Flavia Artizzu2,4, Daniela Marongiu2, Michele Saba2, Andrea Mura2, Giovanni Bongiovanni2, Franco Marabelli1, Francesco Quochi2.
Abstract
Ultrathin films of silica realized by sol-gel synthesis and dip-coating techniques were successfully applied to predefined metal/polymer plasmonic nanostructures to spectrally tune their resonance modes and to increase their sensitivity to local refractive index changes. Plasmon resonance spectral shifts up to 100 nm with slope efficiencies of ∼8 nm/nm for increasing layer thickness were attained. In the ultrathin layer regime (<10 nm), which could be reached by suitable dilution of the silica precursors and optimization of the deposition speed, the sensitivity of the main plasmonic resonance to refractive index changes in aqueous solution could be increased by over 50% with respect to the bare plasmonic chip. Numerical simulations supported experimental data and unveiled the mechanism responsible for the optical sensitivity gain, proving an effective tool in the design of high-performance plasmonic sensors.Entities:
Keywords: Dip-coating; Local Surface Plasmon; Optical Reflectance; Optical Sensing; Sol-gel
Year: 2014 PMID: 26278239 DOI: 10.1021/jz501443c
Source DB: PubMed Journal: J Phys Chem Lett ISSN: 1948-7185 Impact factor: 6.475