Engineering discovery brings invisibility closer to reality

Engineering discovery brings invisibility closer to reality

Since the beginning of recorded time, humans have used materials found in nature to improve their lot. Since the turn of this century, scientists have studied metamaterials, artificial materials engineered to bend electromagnetic, acoustic and other types of waves in ways not possible in nature.

Now, Hao Xin, a professor of electrical and computer engineering at the University of Arizona, has made a discovery with these synthetic materials that may take engineers one step closer to building microscopes with superlenses that see molecular-level details, or shields that conceal military airplanes and even people.

Xin reported his findings with co-authors in an article, "Microwave Gain Medium With Negative Refractive Index," just published in the online journal Nature Communications.

In the UA's Millimeter Wave Circuits and Antennas Laboratory, Xin uses a 3-D printer to make from metals, plastics and other substances. Resembling porous plastic bowling balls and tiny copper wire circuit boards, these objects are configured in precise geometrical patterns to bend waves of energy in unnatural ways. In particular, they exhibit a property called negative refraction, meaning they can bend a wave backward.

Through a prism with negative refraction, a straw leaning in a glass of water would appear inverted: The piece above the water's surface would appear below the water and leaning in the opposition direction.

In a more futuristic scenario, someone looking at a person wearing a cloak with artificially designed refraction properties would see part or none of the person, depending on the cloak's refractive index distribution and whether the light bouncing off of it reached the viewer's eye.

Xin studies how metamaterials affect microwaves. But whether studying microwaves, light waves, sound waves or seismic waves, metamaterials with negative refraction have presented a vexing physics problem for engineers: They reduce the strength of the wave.

"One of the biggest problems with metamaterials is that they produce energy loss," Xin said. "The waves decay as they pass through the artificial material. We have designed a metamaterial that retains negative refraction but does not diminish energy."

In fact, the synthetic material not only prevented energy loss—it actually caused , with the microwave intensifying in strength as it passed through the material. Xin achieved this by embedding simple battery-powered tunnel diodes (a type of semiconductor device) and micronanofabrication technologies into the new material.

"Many people did not think it was possible to achieve energy gain along with negative refraction," Xin said.

He first showed it was possible, with one-dimensional metamaterials, in a paper published in Physical Review Letters in 2011. His new findings reported in Nature Communications have broader implications, because they involve 3-D metamaterials.

The research is funded by the Air Force Office of Scientific Research, or AFOSR. Xin presented his findings in November 2014 at Duke University to scientists with the Tri-Service Metamaterials Program, which promotes collaboration among government, industry and academia to advance metamaterials research and development for the Department of Defense.

Xin, whose research projects also include using breast cancer imaging techniques to detect explosives, conducts his AFOSR-funded metamaterials research with doctoral students in the Millimeter Wave Circuits and Antennas Lab.

"I always wanted to work on metamaterials, due to their interesting physical properties such as ," said UA doctoral student Adnan Kantemur. "I also wanted to be able to fabricate these structures. Most of the research groups I know only study them analytically. In our group, not only are we solving analytic problems, we also have the opportunity to make the metamaterials ourselves."

While Xin works with microwave frequencies, his findings have implications for optical, acoustic and other types of radiation. Metamaterials with both and energy gain properties will help engineers tackle problems of lens diffraction that prevent even the most sophisticated microscopes from probing some extremely tiny materials, including many individual proteins and viruses.

Beyond such superlenses for biomedical and other uses, metamaterials are being studied to produce higher-performance microwave circuits, more energy-efficient and earthquake-resistant buildings, more powerful solar power converters, improved sensor technologies, and ever-smaller antennas that will make wireless devices used for everything from health monitoring to military surveillance more flexible, efficient and practical.

Metamaterials remain in the testing phase. Xin said it will be years before potential fantastical applications like invisibility cloaks actually appear on the market.

But his research is inherently practical, he said, predicting: "Invisibility cloaks will be a reality in my lifetime."


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New metamaterial allows transmission gain while retaining negative refraction property

More information: "Microwave gain medium with negative refractive index." Nature Communications 5, Article number: 5841 DOI: 10.1038/ncomms6841
Citation: Engineering discovery brings invisibility closer to reality (2015, January 26) retrieved 20 September 2019 from https://phys.org/news/2015-01-discovery-invisibility-closer-reality.html
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Jan 26, 2015
So is it reasonable to assume nature could create a shape that produces negative refraction?

Jan 26, 2015
So is it reasonable to assume nature could create a shape that produces negative refraction?

Thanks to naturally occurring humans, yes.

Jan 26, 2015
So is it reasonable to assume nature could create a shape that produces negative refraction?

Thanks to naturally occurring humans, yes.


I used to take this stance until I realized that the word natural actually means "not manmade or caused by mankind." So your statement is false.

I know it seems like a contradiction because humans are not independent of the natural world around us, but until we finally acknowledge that "manmade" is as natural as "beavermade" we should pay attention to the accepted definition of words for consistency. We need to either redefine natural, or use a word that includes humans.

Jan 26, 2015
You mean to tell me that all that fuss about the USS Eldridge in 1943 could have been avoided. No i'm not serious here but being 'invisible' is the wrong term here. One might not be able to see another person but you might hear or smell them. To me being invisible is not enough...being undetectable, now that would be just what the military wanted!

Jan 27, 2015
I used to take this stance until I realized that the word natural actually means "not manmade or caused by mankind." So your statement is false.


I believe we distinguish the difference based on the fact we don't always do it out of necessity..and we can over ride natural requirements. its not necessarily "natural" to build a Hubble telescope, so one argues its not quite the right word to say natural. So man made is a decent phrase to use.

Though we are natural beings we can do things counter to what natural instinct tells us unlike most animals who stick to natural instinct and don't question it.

If we are to be scientific, well we are natural beings so anything we do is technically natural including everything that exists in the entire universe. But that won't win favors to tell people "serial killers is natural" :P Even though they technically are natural in our species.

Jan 27, 2015
One wonders if the amplification of fog penetrating natural radiation frequencies might make driving in dense fog safer.

Jan 28, 2015
It's a bit overkill for fog, considering that automated driving and driving assistance, coupled with optically or otherwise recognizable elements on the road, are technologies that are readily available. That and slowing down.

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