Scientists say they're closer to invisibility material
WASHINGTON (AP) -- Scientists say they are a step closer to developing materials that could render people and objects invisible.
Researchers have demonstrated for the first time they were able to cloak three-dimensional objects using artificially engineered materials that redirect light around the objects.
Previously, they only have been able to cloak very thin two-dimensional objects.
The findings, by scientists at the University of California, Berkeley, are to be released later this week in the journals Nature and Science.
The new work moves scientists a step closer to hiding people and objects from visible light, which could have broad applications, including military ones.
People can see objects because they scatter the light that strikes them, reflecting some of it back to the eye.
Cloaking uses materials, known as metamaterials, to deflect radar, light or other waves around an object.
Metamaterials are mixtures of metal and circuit board materials such as ceramic, Teflon or fibre composite.
here's a picture of three men appearing through the body of tokyo university graduate student kazutoshi obana during a 2003 demonstration of optical camouflage technology:By bending light, researchers appear closer to creating invisibility cloak
The fantasy-like technology offers practical uses, like making computer chips even smaller
By JOHN JOHNSON JR. Los Angeles Times
Aug. 12, 2008, 12:02AM[/size]
Long the stuff of fantasy, practical invisibility shields have been brought a step closer to reality by researchers who say they have engineered materials that can hide an object by bending ordinary light like balloon animals at a circus.
The researchers, led by Xiang Zhang of the Nanoscale Science and Engineering Center at the University of California, Berkeley, have created two composite materials that possess negative refraction indexes, meaning they bend light opposite to the way most natural substances do. If water exhibited negative refraction, fish swimming in a pool would appear to be in the air above the water.
"This is an important step toward creating a cloak," Zhang said Monday.
But he insisted the work was not aimed at shielding Federation starships from Klingon battle cruisers. A more practical application, he said, would be to create a so-called "super lens" that could image infinitesimally small objects, enabling the manufacture of still tinier computer chips.
Materials scientists previously have found two-dimensional materials that cause negative refraction, making an object seem to disappear. But the light-bending properties of these materials were unreliable, the science team said.
The Berkeley researchers, whose work appears this week in the journals Science and Nature, created two different, three-dimensional materials that exhibit negative refraction.
The first method involved stacking alternating layers of silver and magnesium fluoride, a transparent compound used in lenses and windows. Then, tiny fishnet patterns — with holes 860 nanometers apart, or less than one-hundredth the diameter of a human hair — were cut into the layers.
Jason Valentine, a UC Berkeley graduate student, said the layers of fishnet work together to bend the light in an unnatural direction. With further development, the material might eventually be able to bend light entirely around an object, channeling it like water flowing around a rock. With no light reflected back at a viewer, the object would not be visible.
The silver-magnesium fluoride material worked only on light frequencies in the infrared range, beyond the visible spectrum. But with a second technique, researchers succeeded in bending light in the red portion of the visible light spectrum.
The technique involved placing small silver nano-wires inside porous aluminum oxide to accomplish a similar light-channeling ability.
Among the advantages of these new materials is that less light is lost than with the previous two-dimensional materials.
Jie Yao, a graduate student in applied science and technology, said several obstacles remained before the materials could be put into mass production. The material is expensive to produce, and researchers need to demonstrate negative refraction at all wavelengths of visible light, not just red.
They also must overcome the problem of directionality. At the present time, an object coated in the material could appear invisible in one direction but fully visible in another.
Surmounting these barriers will take years, Yao said.
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