How an oxide shell affects the ultraviolet plasmonic behavior of Ga, Mg, and Al nanostructures.
Abstract
The ultraviolet (UV) range presents new challenges for plasmonics, with interesting
applications ranging from engineering to biology. In previous research, gallium, aluminum,
and magnesium were found to be very promising UV plasmonic metals. However, a native
oxide shell surrounds nanostructures of these metals that affects their plasmonic
response. Here, through a nanoparticle-oxide core-shell model, we present a detailed
electromagnetic analysis of how oxidation alters the UV-plasmonic response of spherical
or hemisphere-on-substrate nanostructures made of those metals by analyzing the spectral
evolution of two parameters: the absorption efficiency (far-field analysis) and the
enhancement of the local intensity averaged over the nanoparticle surface (near-field
analysis).
Type
Journal articlePermalink
https://hdl.handle.net/10161/13862Collections
More Info
Show full item recordScholars@Duke
Henry Everitt
Adjunct Professor of Physics
Dr. Everitt is the Army's senior technologist (ST) for optical sciences, a senior
executive currently working for the Army Research Laboratory in Houston, TX. Through
his adjunct appointment in the Duke Physics Department, he leads an active experimental
research group in molecular physics, novel terahertz imaging, nanophotonics, and ultrafast
spectroscopy of wide bandage semiconductors with colleagues on campus and through
an international network of collaborators. Four principal research
Articles written by Duke faculty are made available through the campus open access policy. For more information see: Duke Open Access Policy
Rights for Collection: Scholarly Articles
Works are deposited here by their authors, and represent their research and opinions, not that of Duke University. Some materials and descriptions may include offensive content. More info