Editing Nanoshell (section)

{{Use dmy dates|date=April 2023}}
[[File:Polarization.gif|right|Figure 1. s-polarization and p-polarization]]
{{Nanomedicine_subfields}}

A '''nanoshell''', or rather a nanoshell [[plasmon]], is a type of spherical nanoparticle consisting of a dielectric core which is covered by a thin metallic shell (usually [[gold]]).<ref name=loo>{{cite journal|pmid=14750891|date=Feb 2004|author1=Loo, C|author2=Lin, A|author3=Hirsch, L|author4=Lee, Mh|author5=Barton, J|author6=Halas, N|author7=West, J|author8=Drezek, R|title=Nanoshell-enabled photonics-based imaging and therapy of cancer|volume=3|issue=1|pages=33–40|journal=Technology in Cancer Research & Treatment|url=http://www.tcrt.org/index.cfm?d=3018&c=4130&p=12032&do=detail|format=Free full text|doi=10.1177/153303460400300104|s2cid=17523671|access-date=6 August 2009|archive-url=https://web.archive.org/web/20071023064328/http://www.tcrt.org/index.cfm?d=3018&c=4130&p=12032&do=detail|archive-date=23 October 2007|url-status=usurped|url-access=subscription}}</ref> These nanoshells involve a [[quasiparticle]] called a [[plasmon]] which is a collective excitation or quantum plasma oscillation where the electrons simultaneously oscillate with respect to all the ions.

The simultaneous oscillation can be called plasmon hybridization where the tunability of the oscillation is associated with mixture of the inner and outer shell where they hybridize to give a lower energy or higher energy. This lower energy couples strongly to incident light, whereas the higher energy is an anti-bonding and weakly combines to incident light. The hybridization interaction is stronger for thinner shell layers, hence, the thickness of the shell and overall particle radius determines which wavelength of light it couples with.<ref name=brinson>{{cite journal|doi=10.1021/la802049p|date=Nov 2008|author1=Brinson, Be |author2=Lassiter, Jb |author3=Levin, Cs |author4=Bardhan, R |author5=Mirin, N |author6=Halas, Nj |title=Nanoshells Made Easy: Improving Au Layer Growth on Nanoparticle Surfaces|volume=24|pages=14166–14171|pmid=19360963|pmc=5922771|journal=Langmuir|issue=24}}</ref> Nanoshells can be varied across a broad range of the [[light spectrum]] that spans the visible and near infrared regions. The interaction of light and nanoparticles affects the placement of charges which affects the coupling strength. Incident light polarized parallel to the substrate gives a s-polarization (Figure 1b), hence the charges are further from the substrate surface which gives a stronger interaction between the shell and core. Otherwise, a p-polarization is formed which gives a more strongly shifted plasmon energy causing a weaker interaction and coupling.