Modulating Light by Metal Nanospheres-Embedded PZT Thin-Film

Author

Rosenkrantz, Etai ; Arnon, Shlomi

Author_Institution

Ilse Katz Inst. for Nanoscale Sci. & Technol., Ben-Gurion Univ., Beer-Sheva, Israel

Volume

13

Issue

2

fYear

2014

fDate

Mar-14

Firstpage

222

Lastpage

227

Abstract

We calculated the optical contrast of silver nanospheres embedded in a lead-zirconate-titanate (PZT) film in relation to various volumetric concentrations (<;5%) of the nanospheres using Mie theory to approximate the extinction spectra, after assuming PZT to be isotropic. Then, we determined the nanosphere radius for large shifts in extinction efficiency that yields high contrast (as high as 12.74 dB), this radius was 7.4 nm. A device based on this nanocomposite film will be able to modulate light in the visible spectrum with sharp contrast between its “on” and “off” state at high speed and with low power consumption.

Keywords

extinction coefficients; ferroelectric thin films; lead compounds; nanocomposites; silver; visible spectra; zirconium compounds; Ag-PZT; Mie theory; extinction spectra; isotropic PZT; lead-zirconate-titanate film; light modulation; metal nanosphere-embedded PZT thin-film; nanocomposite film; nanosphere radius; optical contrast; power consumption; radius 7.4 nm; silver nanospheres; visible spectrum; volumetric concentrations; Electric fields; Metals; Optical films; Optical modulation; Optical scattering; Ferroelectric films; modulation; nanotechnology; optoelectronic devices; plasmonics; scattering;

fLanguage

English

Journal_Title

Nanotechnology, IEEE Transactions on

Publisher

ieee

ISSN

1536-125X

Type

jour

DOI

10.1109/TNANO.2013.2297833

Filename

6702443