How to trap a rainbow
November 27th, 2009 - 12:19 pm ICT by ANI ( Leave a comment )London, November 27 (ANI): In a new research, scientists have used a convex lens to trap a rainbow for the first time.
In 2007, Ortwin Hess of the University of Surrey in Guildford, UK, and colleagues proposed a technique to trap light inside a tapering waveguide, which is a structure that guides light waves down its length.
The waveguide in question would use metamaterials - exotic materials that can bend light sharply.
The idea is that as the waveguide tapers, the components of the light are made to stop in turn at ever narrower points.
That’s because any given component of the light cannot pass through an opening that’s smaller than its wavelength.
This leads to a “trapped rainbow”.
While numerical models showed that such waveguides would work in theory, making them out of metamaterials remained a distant dream.
Now, according to a report in New Scientist, Vera Smolyaninova of Towson University in Baltimore, Maryland, and colleagues have used a convex lens to create the tapered waveguide and trap a rainbow of light.
They coated one side of a 4.5-millimetre-diameter lens with a gold film 30 nanometre thick, and laid the lens - gold-side down - on a flat glass slide which was also coated with film of gold.
Viewed side-on, the space between the curved lens and the flat slide was a layer of air that narrowed to zero thickness where the lens touched the slide - essentially a tapered waveguide.
When they shone a multi-wavelength laser beam at the open end of the gilded waveguide, a trapped rainbow formed inside.
This could be seen as a series of coloured rings when the lens was viewed from above with a microscope: the visible light leaked through the thin gold film.
Shorter-wavelength green light was trapped at a point where the taper became too thin for it to penetrate the waveguide.
Longer-wavelength red light was trapped further out, where the taper was thicker, with intermediate wavelengths in between
“I think it’s beautiful that we can create such complex phenomena using a very, very simple configuration. It’s amazing,” said Smolyaninova. (ANI)
- Rainbow-trapping scientist opens up new possibilities for data storage - Apr 13, 2011
- Oz scientists' theory brings invisibility cloaks closer to reality - Aug 29, 2010
- New kind of optical fiber paves way for improved surgical and medical lasers - Feb 26, 2011
- Harry Potter-style invisibility cloak can now be made from silk - Aug 12, 2010
- Scientists unveil simpler-to-manufacture 'broadband' cloaking technology - May 21, 2009
- Harry Potter's invisibility cloak may become a reality - Nov 04, 2010
- Now, view 3-D delights sans the pesky specs - Jun 16, 2010
- Miniature invisibility 'carpet cloak' shows promise for the optical world - Apr 20, 2011
- Star Trek 'teleportation' could be a reality soon - Mar 04, 2011
- New materials could make invisibility cloak technology a reality - Jan 26, 2011
- Scientists make first perovskite-based superlens for the infrared - Mar 30, 2011
- New process improves solar cell efficiency by 20pc - Dec 03, 2010
- 'Blacker than black' metamaterial created - Jun 12, 2010
- Liquid invisibility cloak may soon be a reality - Jan 09, 2010
- Is the Star-trek style invisibility cloak finally a reality? - Feb 02, 2011
Tags: coloured rings, convex lens, distant dream, exotic materials, flat glass, flat slide, glass slide, gold film, gold side, light waves, nanometre, new scientist, numerical models, rainbow london, research scientists, thin gold, towson university, university of surrey, waveguide, wavelength laser
