Search
Menu
Meadowlark Optics - Wave Plates 6/24 LB 2024

Gold Glitters Differently at the Nanoscale

Facebook X LinkedIn Email
ARGONNE , Ill. Jan. 17, 2006 -- Researchers at the US Department of Energy's Argonne National Laboratory have found that gold "shines" in a different way at the nanoscale, and the insights may lead to new optical chips for computers or for switches and routers in fiber networks.
The nanoscale refers to a size one-billionth of a meter, or about 70,000 times smaller than the width of a human hair. Materials that small exhibit entirely different properties from conventional materials. Specifically, temperature, electricity and magnetism are completely different from that of conventional materials, and could form the basis of new technologies.
The Argonne researchers examined the characteristics of photoluminescence -- the emission of light when electrons are stimulated -- in gold nanorods, and found that they could control the wavelength of the light emitted by the material, making it possible to use as a light source inside an optical chip, allowing transmission of information through light. "The light emitted is dependent on the shape of the gold nanorods," said Gary Wiederrecht, Argonne scientist and leader of the research team.
The gold nanorods are about 20 nm wide and range from 70 to 300 nm long. The rod-like shape of the material is important, Wiederrecht explained, because the rod shape determines the energy of the collective electronic excitations that radiate light. Thus, photoluminescence at different wavelengths is achieved in nanorods of differing lengths. The rod shape also produces enhanced absorption of the illumination, increasing the light intensity and also concentrating that intensity to levels high enough to create luminescence. "The rods have strong absorption characteristics in the near-infrared range," Wiederrecht said. The experimenters used an ultrafast titanium-sapphire laser beam at 800 nm to create the photoluminescence.

Opto Diode Corp. - Detector Spotlight 10-24 MR
While the research has future implications for technological advances, Wiederrecht is quick to explain that his group has done basic research -- an examination of the material for a fundamental understanding of its characteristics. The longer-term implications of the work include the ability to produce nanoscale light sources for faster and smaller optical devices and novel photoluminescent sensors.
"Because materials at the nanoscale behave so differently from conventional materials, we're starting all over again, in a way, to understand how and why these nanomaterials function," Wiederrecht said. Other members of the research team are lead author Alexandre Bouhelier of Argonne's Chemistry Div. and the Center for Nanoscale Materials and Renaud Bachelot, Gilles Lerondel, Sergei Kostcheev and Pascal Royer, all of the Laboratoire de Nanotechnologie et d'Instrumentation Optique in Troyes, France.
The research was published in the Dec. 31 issue of Physical Review Letters. For more information, visit: www.anl.gov

Published: January 2006
Glossary
photoluminescence
Photoluminescence is a phenomenon in which a material absorbs photons (light) at one wavelength and then re-emits photons at a longer wavelength. This process occurs when electrons in the material are excited to higher energy states by absorbing photons and subsequently return to lower energy states, emitting photons in the process. The emitted photons have less energy and longer wavelengths than the absorbed photons. Photoluminescence can be broadly categorized into two types: ...
ArgonneBasic SciencegoldNanorodsnanoscaleNews & Featuresoptical chipsphotoluminescenceSensors & DetectorsWiederrecht

We use cookies to improve user experience and analyze our website traffic as stated in our Privacy Policy. By using this website, you agree to the use of cookies unless you have disabled them.