The reflection pattern from an uncloaked
object on a flat surface (top) compared to the reflection pattern of the
same object covered with the cloaking device (bottom), which
effectively mimics the reflection from a completely flat surface.
Credit: Li-Yi Hsu/Jacobs School of Engineering/UC San Diego
Researchers have developed a new design for a
cloaking device that overcomes some of the limitations of existing
"invisibility cloaks." In a new study, electrical engineers at the
University of California, San Diego have designed a cloaking device that
is both thin and does not alter the brightness of light around a hidden
object. The technology behind this cloak will have more applications
than invisibility, such as concentrating solar energy and increasing
signal speed in optical communications.
"Invisibility may seem like magic at first, but its underlying
concepts are familiar to everyone. All it requires is a clever
manipulation of our perception," said Boubacar Kanté, a professor in the
Department of Electrical and Computer Engineering at the UC San Diego
Jacobs School of Engineering and the senior author of the study. "Full
invisibility still seems beyond reach today, but it might become a
reality in the near future thanks to recent progress in cloaking
devices."
As their name implies, cloaks are devices that cover objects to make
them appear invisible. The idea behind cloaking is to change the
scattering of electromagnetic waves -- such as light and radar -- off an
object to make it less detectable to these wave frequencies.
One of the drawbacks of cloaking devices is that they are typically bulky.
"Previous cloaking studies needed many layers of materials to hide an
object, the cloak ended up being much thicker than the size of the
object being covered," said Li-Yi Hsu, electrical engineering Ph.D.
student at UC San Diego and the first author of the study, which was
recently published in the journal Progress In Electromagnetics Research. "In this study, we show that we can use a thin single-layer sheet for cloaking."
The researchers say that their cloak also overcomes another
fundamental drawback of existing cloaking devices: being "lossy." Cloaks
that are lossy reflect light at a lower intensity than what hits their
surface.
"Imagine if you saw a sharp drop in brightness around the hidden
object, it would be an obvious telltale. This is what happens when you
use a lossy cloaking device," said Kanté. "What we have achieved in this
study is a 'lossless' cloak. It won't lose any intensity of the light
that it reflects."
Many cloaks are lossy because they are made with metal particles,
which absorb light. The researchers report that one of the keys to their
cloak's design is the use of non-conductive materials called
dielectrics, which unlike metals do not absorb light. This cloak
includes two dielectrics, a proprietary ceramic and Teflon, which are
structurally tailored on a very fine scale to change the way light waves
reflect off of the cloak.
In their experiments, the researchers specifically designed a
"carpet" cloak, which works by cloaking an object sitting on top of a
flat surface. The cloak makes the whole system -- object and surface --
appear flat by mimicking the reflection of light off the flat surface.
Any object reflects light differently from a flat surface, but when the
object is covered by the cloak, light from different points is reflected
out of sync, effectively cancelling the overall distortion of light
caused by the object's shape.
"This cloaking device basically fools the observer into thinking that there's a flat surface," said Kanté.
The researchers used Computer-Aided Design software with
electromagnetic simulation to design and optimize the cloak. The cloak
was modeled as a thin matrix of Teflon in which many small cylindrical
ceramic particles were embedded, each with a different height depending
on its position on the cloak.
"By changing the height of each dielectric particle, we were able to
control the reflection of light at each point on the cloak," explained
Hsu. "Our computer simulations show how our cloaking device would behave
in reality. We were able to demonstrate that a thin cloak designed with
cylinder-shaped dielectric particles can help us significantly reduce
the object's shadow."
"Doing whatever we want with light waves is really exciting," said
Kanté. "Using this technology, we can do more than make things
invisible. We can change the way light waves are being reflected at will
and ultimately focus a large area of sunlight onto a solar power tower,
like what a solar concentrator does. We also expect this technology to
have applications in optics, interior design and art."
This work was supported by a grant from the Calit2 Strategic Research
Opportunities (CSRO) program at the Qualcomm Institute at UC San Diego.
Story Source:
The above post is reprinted from
materials provided by
University of California - San Diego.
Note: Materials may be edited for content and length.
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