Dr Shengli Zou's research group at University of Central Florida is currently working on research in the field of nanoparticles and their properties pertaining to light transmittance and absorption.  This web page is designed to aid in understanding how materials respond to light energy changes and how that affects materials on a molecular scale.

Plasmonics
Text Box: Def. The study of density waves of electrons (plasmons) that are created when light hits the surface of a metal at precise circumstances, that is, at the structure¡¯s resonance energy level. The resonance energy corresponds to the wavelength absorption that occurs. If a band of wavelengths strike the metallic object the non-absorbed wavelengths will reflect, causing the structure to have color. Diagram of wave propagation and particle plasmon oscillation

Fig a. resonance on a thin sheet of metal Fig b. resonance on a single particle note that the light blue electron cloud is oscillating toward and away from the electric field.

 

Resonance frequency--def.  Maximum oscillation at specific frequencies. Each size and shape nanoparticle represents a different resonance frequency.  For more information about resonance these web sites may help.  In the first animation when the force applied matches the maximum spring constant resonance occurs.  Similarly, when the wavelength frequency matches the resonance energy maximum oscillation of the plasmons occur.

http://ngsir.netfirms.com/englishhtm/Resonance.htm

http://www.pbs.org/wgbh/nova/elegant/resonance.html

 

 

These surface plasmons  occur at the interface of a metal and a dielectric material.   The optic properties of these  surface plasmons can be determined in two ways.

           1.  By using spectroscopy equipment in a laboratory setting.

                      Or

           2.  By using computer modeling with  a program called Discrete Dipole Approximation (DDA)

 

 
Text Box: Surface plasmons (SP's) are electromagnetic waves that propagate ( travel )at the interface between metals and dielectric (non conductive) material. This simulates the propagation of surface plasmons on Ag-air interface, the color indicates the magnitude or strength of electric field (blue for positive and red for negative).  The source for SP¡¯s is a point dipole and is placed at the center. In this simulation, you can also see strong localization of these waves at the interface. The plasmon behavior has attracted the attention of researchers in engineering, physics and chemistry communities. Animation provided by http://juluribk.com/ Animation of waves moving along a surface using properties of surface plasmons

This web page was created by Kay Miraglia for the purpose of educating the high school public regarding nanomaterial  research at University of Central Florida.  You can contact Kay at kay_miraglia (at) scps.k12.fl.us

 

 

 

omputational

Nanomaterial

hemistry
animation of oscillating electron cloudText Box:

A chemistry research group that focuses on simulating structure and characteristics of novel nanomaterials

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