Topic: Metamaterials: a real invisibility cloak

[Thucydides]

Canada is becoming a leader in the investigation of "Metamaterials". Rather than go into the physics (which is rather freaky) the effect of metamaterials is to bend light, radio and radar waves in unexpected directions. By careful control of the material, you could literally bend light  or radar around an object, rendering it effectively transparent. Rather bizzare effects could be engineered into antennas and lenses using these materials, perhaps reducing the size of the lens compared to an equally powerful conventional optical device, creating powerful surveillance systems which could be incorporated into hand held devices.

Metamaterials working in the microwave frequency range are now being studied, and in 2005, a simple prototype that works with visible light frequencies was demonstrated.

There is an introduction in the October edition of Popular Science, and http://www.nserc.ca/news/2004/p040311_bio3.htm.

[warspite]

Not sure where to post this. Please move if it's in the wrong place.
http://www.cbc.ca/technology/story/2006/10/19/invisibility-cloak.html#skip300x250

Scientists create 'invisibility' cloak that bends microwaves
Last Updated: Thursday, October 19, 2006 | 12:09 PM ET
CBC News
A team of British and U.S. scientists has demonstrated the first working "invisibility cloak," although don’t expect it to appear in the Halloween costumes aisle just yet.

The team, led by Professor Sir John Pendry of Imperial College in London, built the prototype at Duke University in North Carolina and reported its findings Thursday in Science Express, the advance online publication of the journal Science.

Little more than 12 centimetres across, the small device can redirect microwave beams so they flow around a "hidden" object inside with little distortion, making it appear almost as if nothing were there at all.

Like light, microwaves bounce off objects, making them visible and creating a "shadow," although it has to be detected with instruments.

The new work could be a baby step to an improved version that would make the Klingons and Harry Potter jealous by hiding people and objects from visible light.

Like 'water flowing around a smooth rock'

In the experiment, the scientists used microwaves to try to detect a copper cylinder "hidden" by the cloak, which is made from metamaterials — or engineered mixtures of metal and circuit board materials, which could include ceramic, Teflon or fibre composite materials.

"The waves' movement is similar to river water flowing around a smooth rock,” said cloak designer David Schurig, a research associate in Duke's electrical and computer engineering department.

The test came five months after the team published a theory that such a device was possible to design.

"By incorporating complex material properties, our cloak allows a concealed volume, plus the cloak, to appear to have properties similar to free space when viewed externally," said David Smith, a professor of electrical and computer engineering at Duke, in a release Thursday.

"The cloak reduces both an object's reflection and its shadow, either of which would enable its detection."

Wireless, radar applications

Cloaking differs from stealth technology, which doesn't make an aircraft invisible but reduces the cross-section available to radar, making it hard to track. Cloaking simply passes the radar or other waves around the object as if it weren't there.

Cloaks that render objects essentially invisible to microwaves could have a variety of wireless communications or radar applications, the researchers said.

The scientists said their cloak represents the most comprehensive approach to invisibility yet realized, with the potential to hide objects of any size or material property.

Earlier scientific approaches to achieving "invisibility" often relied on limiting the reflection of electromagnetic waves, they added.
 

Could this have serious military application? Even if it could only hide a target from radar etc, it would seem to me to have enormous potential. Comments?

[Beadwindow 7]

Could you imagine?

This would be an amazing resource for ECW. Imagine hiding your CPs or RRBs from Directional Finding?

[MCG]

Could this have serious military application? Even if it could only hide a target from radar etc, it would seem to me to have enormous potential. Comments?

Eventually, yes.  Probably not for a while.

Could you imagine?

This would be an amazing resource for ECW. Imagine hiding your CPs or RRBs from Directional Finding?

I don't think this will hide a transmitter from direction finding.  It would hide things from the ambient EM spectrum (including from detection systems that look for a return of their own EM broadcasts).

[Trinity]

How much energy would this thing need.   

Definitely NOT feasible for the next 20-30 years?

[Klc]

As the article said. You can hide a small copper rod from microwaves. If you can find a use for that... 

[MCG]

Today it's a rod.  In 25 years it could be a tank, destroyer or attack fighter that is hidden.

[warspite]

From theory to hiding this small copper rod, took five months. From here it would just be a matter of increasing the scale and efficiency. The main problem, as Trinity has said, will be how much power this thing will use to operate.

[Bert]

The trick to the technology is HOW it redirects microwaves, if "redirects" is the word to
accurately describe what the device does.  The article specifies microwaves but other
electromagnetic spectrums are not listed.

"Visibility" of radar usually within microwave bands rely on signal reflection or discernable
changes across a transmission field.  The technology would reduce the reflection by the
redirection of radar pulses and minimize discernable changes in RF fields.  Speculative
applications may involve radar/RF object detection countermeasures or in the reduction
of damaging solar/high power RFI fields.

[MCG]

Bert ,
You are describing stealth technology when you talk of redirecting the radar pulses.  That is not what is described above (in which the radar pulses would still be seen undisturbed on the far side of the object).  When this technology is made to work (at it may be a very many years) then you would no longer be able to detect stealth aircraft through passive stations looking for scattered EM waves.

[Bert]

Sorry McG, I'm taking this right from the article:

>
Little more than 12 centimetres across, the small device can redirect microwave beams so they flow around a "hidden" object inside with little distortion, making it appear almost as if nothing were there at all.
<

The article doesn't provide a full scientific concept or technical specifications of the wave redirection.  It does specify
"microwaves" which are a small part of the electromagnetic spectrum and redirect with "little" distortion.  The radar does
detect reflections so the device may minimize or eliminate discernable radar signatures.  I was speculating the device could also mask
objects passing through X-ray machines or lower/redirect solar RFI that affects satellites in time to come.

[MCG]

The goal of the technology is no reflection/scattering.  You noted yourself (your first post above) that "redirects" does not fit the technology description.  I agree that the device could mask objects passing through X-ray machines, and this is probably much nearer in the future that any battlefield application.

Crude invisibility cloak unveiled
Device makes microwaves slip around object
Oct. 19, 2006. 11:04 AM
RANDOLPHE E. SCHMID
ASSOCIATED PRESS

WASHINGTON - Harry Potter and Captain Kirk would be proud. A team of American and British researchers has made a Cloak of Invisibility.
Well, OK, it’s not perfect. Yet.

But it’s a start, and it did a pretty good job of hiding a copper cylinder from microwave detection.

Like light and radar waves, microwaves bounce off objects making them visible and creating a shadow, though it has to be detected with instruments.
And if you can hide something from microwaves, you can hide it from radar — a possibility that will fascinate the military — and likely from eyesight as well.

Cloaking differs from stealth technology, which doesn’t make an aircraft, ships and other objects invisible but reduces the cross-section available to radar, making it hard to track.

Cloaking simply passes the radar or other waves around the object as if it weren’t there, like water flowing around a smooth rock in a stream.
The new work points the way for an improved version that could even hide people and objects from visible light.

Conceptually, the chance of adapting the concept to visible light is good, cloak designer David Schurig said in a telephone interview.

But Schurig, a research associate in Duke University’s electrical and computer engineering department, added: “From an engineering point of view it is very challenging.”

[andreit1]

I would give it a maximum of 10 years before it is applied
to actual combat. Although by then a counter measure will surely have emerged. I say we go
back to fighting with our fists. 

[Aden_Gatling]

Outta' control  ... just came across a video of this technology (wait for the end to check out the jacket): http://www.youtube.com/watch?v=VVi7mZ6XX3w

[warspite]

http://projects.star.t.u-tokyo.ac.jp/projects/MEDIA/xv/oc.html
It's actually quite ingenious. As far as I can tell the reflective material only reflects the image you project, hence with an image of the background it masks the object behind it. Not an expert but should have potential for base security or security for any fixed location in general.

[geo]

http://news.bbc.co.uk/2/hi/science/nature/7553061.stm

Scientists in the US say they are a step closer to developing materials that could render people invisible.

Researchers at the University of California in Berkeley have developed a material that can bend light around 3D objects making them "disappear".
The materials do not occur naturally but have been created on a nano scale, measured in billionths of a metre.
The team says the principles could one day be scaled up to make invisibility cloaks large enough to hide people.

Stealth operations

The findings, by scientists led by Xiang Zhang, were published in the journals Nature and Science.
The light-bending effect relies on reversing refraction, the effect that makes a straw placed in water appear bent.
Previous efforts have shown this negative refraction effect using microwaves—a wavelength far longer than humans can see.
The new materials instead work at wavelengths around those used in the telecommunications industry—much nearer to the visible part of the spectrum.
Two different teams led by Zhang made objects made of so-called metamaterials—artificial structures with features smaller than the wavelength of light that give the materials their unusual properties.

One approach used nanometre-scale stacks of silver and magnesium fluoride in a "fishnet" structure, while another made use of nanowires made of silver.
Light is neither absorbed nor reflected by the objects, passing "like water flowing around a rock," according to the researchers. As a result, only the light from behind the objects can be seen.

Cloak and shadow

"This is a huge step forward, a tremendous achievement," says Professor Ortwin Hess of the Advanced Technology Institute at the University of Surrey.
"It's a careful choice of the right materials and the right structuring to get this effect for the first time at these wavelengths."
There could be more immediate applications for the devices in telecommunications, Prof Hess says.
What's more, they could be used to make better microscopes, allowing images of far smaller objects than conventional microscopes can see.

And a genuine cloaking effect isn't far around the corner.

"In order to have the 'Harry Potter' effect, you just need to find the right materials for the visible wavelengths," says Prof Hess, "and it's absolutely thrilling to see we're on the right track."

[army08]

I read and wrote on an article on usenet a number of years back. It was essentially just a matter of having a light absorbant material that could also reflect those colours around it - cloaking. Or in the case of invisibility take the signal then transmit the signal from one side, map the digital characteristics of the space from point A to point b and display it. I have no doubts this technology existed over 5 years ago. in a 1 meter x 1 meter sized drone.

[Thucydides]

Metamaterials do not absorb wavelengths of light (or sound, there are some threads on metamaterials in the navy board and elsewhere in Army.ca), but rather refract them in a controlled manner. Think of how light is refracted in a glass of water when you dunk a spoon in it; the spoon looks broken where the light is refracted.

Metamaterials control the refraction in the manner the designer plans, metamaterials already exist for radio and microwave frequencies (imagine bending a radar beam around an aircraft or ship), and have been demonstrated for light and sound as well. invisibility in all wavelengths will be difficult to achieve, since refraction is a property of the wavelength of the light, radio or sound wave you are trying to bend, but even limited invisibility would be pretty freaky.

[GAP]

Especially in various forms of covert ops, etc.....

[Thucydides]

More on Metamaterials:

http://www.technologyreview.com/Nanotech/21213/?nlid=1268&a=f

Bringing Invisibility Cloaks Closer
The fabrication of two new materials for manipulating light is a key step toward realizing cloaking.
By Katherine Bourzac

In an important step toward the development of practical invisibility cloaks, researchers have engineered two new materials that bend light in entirely new ways. These materials are the first that work in the optical band of the spectrum, which encompasses visible and infrared light; existing cloaking materials only work with microwaves. Such cloaks, long depicted in science fiction, would allow objects, from warplanes to people, to hide in plain sight.

Both materials, described separately in the journals Science and Nature this week, exhibit a property called negative refraction that no natural material possesses. As light passes through the materials, it bends backward. One material works with visible light; the other has been demonstrated with near-infrared light.

The materials, created in the lab of University of California, Berkeley, engineer Xiang Zhang, could show the way toward invisibility cloaks that shield objects from visible light. But Steven Cummer, a Duke University engineer involved in the development of the microwave cloak, cautions that there is a long way to go before the new materials can be used for cloaking. Cloaking materials must guide light in a very precisely controlled way so that it flows around an object, re-forming on the other side with no distortion. The Berkeley materials can bend light in the fundamental way necessary for cloaking, but they will require further engineering to manipulate light so that it is carefully directed.

One of the new Berkeley materials is made up of alternating layers of metal and an insulating material, both of which are punched with a grid of square holes. The total thickness of the device is about 800 nanometers; the holes are even smaller. "These stacked layers form electrical-current loops that respond to the magnetic field of light," enabling its unique bending properties, says Jason Valentine, a graduate student in Zhang's lab. Naturally occurring materials, by contrast, don't interact with the magnetic component of electromagnetic waves. By changing the size of the holes, the researchers can tune the material to different frequencies of light. So far, they've demonstrated negative refraction of near-infrared light using a prism made from the material.

Researchers have been trying to create such materials for nearly 10 years, ever since it occurred to them that negative refraction might actually be possible. Other researchers have only been able to make single layers that are too thin--and much too inefficient--for device applications. The Berkeley material is about 10 times thicker than previous designs, which helps increase how much light it transmits while also making it robust enough to be the basis for real devices. "This is getting close to actual nanoscale devices," Cummer says of the Berkeley prism.

The second material is made up of silver nanowires embedded in aluminum. "The nanowire medium works like optical-fiber bundles, so in principle, it's quite different," says Nicholas Fang, mechanical-science and -engineering professor at the University of Illinois at Urbana-Champagne, who was not involved in the research. The layered grid structure not only bends light in the negative direction; it also causes it to travel backward. Light transmitted through the nanowire structure also bends in the negative direction, but without traveling backward. Because the work is still in the early stages, it's unclear which optical metamaterial will work best, and for what applications. "Maybe future solutions will blend these two approaches," says Fang.

Making an invisibility cloak will pose great engineering challenges. For one thing, the researchers will need to scale up the material even to cloak a small object: existing microwave cloaking devices, and theoretical designs for optical cloaks, must be many layers thick in order to guide light around objects without distortion. Making materials for microwave cloaking was easier because these wavelengths can be controlled by relatively large structural features. To guide visible light around an object will require a material whose structure is controlled at the nanoscale, like the ones made at Berkeley.

Developing cloaking devices may take some time. In the short term, the Berkeley materials are likely to be useful in telecommunications and microscopy. Nanoscale waveguides and other devices made from the materials might overcome one of the major challenges of scaling down optical communications to chip level: allowing fine control of parallel streams of information-rich light on the same chip so that they do not interfere with one another. And the new materials could also eventually be developed into lenses for light microscopes. So-called superlenses for getting around fundamental resolution limitations on light microscopes have been developed by Fang and others, revealing the workings of biological molecules with nanoscale resolution using ultraviolet light, which is damaging to living cells in large doses. But it hasn't been possible to make superlenses that work in the information-rich and cell-friendly visible and near-infrared parts of the spectrum.

Copyright Technology Review 2008.

[tomahawk6]

Cant have a cloak without an energy shield.
All we need for our space ship is a warp drive.

[Ecco]

All we need for our space ship is a warp drive.

Here is your warp drive.
http://dsc.discovery.com/news/2008/07/28/warp-speed-engine.html

[Thucydides]

A broadband invisibility cloak is now within reach. Given that lightwaves are much smaller than sound or radio waves, it will be easier in theory to "cloak" aircraft and AFV's from radar, and submarines from sonar than to make objects disappear in the visible spectrum. My main question now is how well does this stuff work in controlling leakage of energy from the shielded object? (Damn, what is that thermal hotspot in the middle of the open field?)

Exciting stuff

http://www.technologyreview.com/computing/21971/?nlid=1694&a=f

Friday, January 16, 2009
Invisibility-Cloak Breakthrough
New software has enabled metamaterials to work with a broad band of frequencies.
By Katherine Bourzac

Metamaterials interact with light in ways that appear to violate the laws of physics. They can bend light around an object as if it weren't there, or narrow the resolution of light microscopes down to a few nanometers. But metamaterials must be painstakingly structured at the nano- and microscales in order to achieve these exotic effects. Now the Duke University researcher who built the first invisibility cloak in 2006 has created software that speeds up the design of metamaterials. He and his colleagues have used the program to build a complex light cloak that's invisible to a broad band of microwave light--and they did it in only about 10 days.

David R. Smith of Duke and Tai Jun Cui of Southeast University, in Nanjing, China, led the work, which is a landmark in the field of metamaterials. The cloak that the researchers built works with wavelengths of light ranging from about 1 to 18 gigahertz--a swath as broad as the visible spectrum. No one has yet made a cloaking device that works in the visible spectrum, and those metamaterials that have been fabricated tend to work only with narrow bands of light. But a cloak that made an object invisible to light of only one color would not be of much use. Similarly, a cloaking device can't afford to be lossy: if it lets just a little bit of light reflect off the object it's supposed to cloak, it's no longer effective. The cloak that Smith built is very low loss, successfully rerouting almost all the light that hits it.

"Their cloak . . . answers the naysayers who predicted that cloaks would always be narrowband and lossy," says John Pendry, chair in theoretical solid-state physics at Imperial College London. Pendry did the theoretical work upon which both the first invisibility cloak and its new successor are based. "Needless to say, I am delighted with this development," says Pendry. He and his Imperial College colleague Jensen Li proposed a theoretical version of a broadband cloak just last year, and at that time, he says, he "did not expect such rapid experimental progress."

The broadband cloak is a rectangular structure measuring about 50 by 10 centimeters, with a height of about 1 centimeter. It's made up of roughly 600 I-shaped copper structures. Making each structure is a simple matter, says Smith. "They're copper patterns on a circuit board, cut up and arranged. It's a well-known, inexpensive technology." The hard part is determining the dimensions of each of these 600 structures and how to arrange them. With the first light cloak, which had only 10 such pieces, "we had to design each element by numerical simulations," Smith says. Applying the same approach to the more complicated cloak would have eaten up months.

Even for physicists and engineers, the math involved in the theoretical design of cloaking devices is very difficult, says Nicholas Fang, a professor of mechanical science and engineering at the University of Illinois at Urbana-Champaign. The way that a material interacts with light's magnetic and electric components is taken into account in determining the size, shape, and orientation of each structure in a metamaterial. Pendry and Li's theoretical work described how to make a broadband cloak by using materials structured so that they have an electrical response to light, but not a magnetic one. But it wasn't clear how to put this idea into practice. The Southeast University researchers developed new algorithms to greatly speed up the process, says Smith. These algorithms make it possible to quickly predict how a structure with a particular shape will interact with light.

The cloak itself, described this week in Science, is indeed impressive, says Fang, who's working on metamaterials for super-resolution biological imaging. But what's more exciting is that the new approach to design will accelerate the development of other metamaterials. Smith says that he and his group have already moved beyond the cloak reported in Science, but because their latest work is unpublished, he can't specify what they've made. "Now [that] this is becoming a more feasible technology," he says, "we will start to see a lot more of it."

Other applications of metamaterials, says Smith, include optical devices that take light energy and concentrate it, instead of turning it away--conceptually, the opposite of a cloak. "You could improve solar cells by making structures to increase the field strength of the light," he says. The new work suggests that this could be done over the whole spectrum of wavelengths found in sunlight. Similarly, broadband "hyperlenses" that gather up light missed by normal lenses could revolutionize biological imaging. Fang and others have developed narrowband hyperlenses with resolutions of only a few nanometers, which make the molecular workings of cells visible. A broadband hyperlens could work with all colors of visible and infrared light.

The ultimate goal, says Pendry, is cloaking in the visible-light spectrum, and Smith's latest work points the way forward. "There are no insuperable obstacles to making a cloak work at optical frequencies," Pendry says. "The Duke paper brings this goal a step closer."

Copyright Technology Review 2009.

[Thucydides]

Notice this is a flat plate of material. This form factor is much easier to work with when building an actual object:

http://www.technologyreview.com/blog/arxiv/23270/?nlid=1908

Acoustic superlens could cloak objects from sonar

First experimental demonstration of a technology that could trigger a new game of cat and mouse beneath the waves
Wednesday, April 01, 2009

Researchers have been messing about with optical metamaterials and invisibility cloaks for a few years now. And while progress has been rapid, nobody's going to be fooling Voldemort any time soon.

But the same exotic tricks that apply to light can equally be applied to sound. And potentially more easily too because sound has a longer wavelength. The business parts of acoustic metamaterials should therefore be significantly easier to build than their optical counterparts.

And that's just what Nicholas Fang and buddies from the University of Illinois at Urbana- Champaign have done: create a flat slab of acoustic metamaterial that focuses sound with a negative refractive index. They've even fashioned a design that works as a "superlens" that focuses the so-called evanescent sound waves that form within a single wavelength of the source-- a world first apparently.

Fang and co have created an acoustic metamaterial by carving an array of holes into an aluminium sheet and filling the holes with water. The holes then resonate when water moves over them, like wind over the mouth of a bottle.

In theory, superlenses can far outperform the resolution of conventional lenses but Fang's lens isn't super just yet: its resolution is only about half the length of the incident waves. But that's pretty good and among the best that has ever been possible with purely passive focusing elements. And while conventional optics can never beat this kind of resolution, Fang's superlenses can almost certainly be improved.

Another big advantage is the shape of the lens which is entirely flat and just a few centimetres square. That makes it much easier to make than the spherical optics that have been necessary in the past.

Obviously, the new technique will be handy for medical imaging and nondestructive testing but the authors hint at a more exotic application. They say:

    "This design approach may lead to novel strategies of acoustic cloak for camouflage under sonar.

Tantalising! What on Earth could they mean?

[Recon 3690]

This brings to mind the 2 Philadelphia Experiment movies

[Thucydides]

Now other types of all aspect invisibility cloaks are being developed. Imagine being able to bring a smart weapon very close to the target before disclosing yourself by firing (or cruising far away and letting the weapon do an unpowered separation inside its own cloak before going active and hunting the target down?)

One aspect which is even more interesting is using this sort of technology "bend" earthquake and tsunami waves around an object. Can you bend shockwaves around a target and protect a military target from a near miss?

http://nextbigfuture.com/2009/08/numerically-shown-multiple-frequency.html

Numerically Shown Multiple Frequency Active Cloaking of Any Shape Object by Devices that Generate EM

These images are from animated computer simulations of a new method -- developed by University of Utah mathematicians -- for cloaking objects from waves of all sorts. While the new method is unlikely to lead to invisibility cloaking like that in 'Star Trek' or 'Harry Potter' movies, it may eventually help shield submarines from sonar, planes from radar, buildings from earthquake waves, and oil rigs and coastal structures from tsunamis. The top three images show a wave front passing the kite-shaped object in the middle and hitting the object as it does. In the bottom three images, the kite-shaped object if surrounded by three cloaking devices and the waves they emit. So when the wave front passes, it moves by the object without touching it. Photo Credit: Fernando Guevara Vasquez

University of Utah mathematicians developed a new cloaking method which someday might shield submarines from sonar, planes from radar, buildings from earthquakes, and oil rigs and coastal structures from tsunamis.


We have shown that it is numerically possible to cloak objects of any shape that lie outside the cloaking devices, not just from single-frequency waves, but from actual pulses generated by a multi-frequency source," says Graeme Milton, senior author of the research and a distinguished professor of mathematics at the University of Utah.

It's called active cloaking, which means it uses devices that actively generate electromagnetic fields rather than being composed of 'metamaterials' [exotic metallic substances] that passively shield objects from passing electromagnetic waves."

Radar microwaves have wavelengths of about four inches, so Milton says the study shows it is possible to use the method to cloak from radar something 10 times wider, or 40 inches. That raises hope for cloaking larger objects. So far, the largest object cloaked from microwaves in actual experiments was an inch-wide copper cylinder.

Most previous research used interior cloaking, where the cloaking device envelops the cloaked object. Milton says the new method "is the first active, exterior cloaking" technique: cloaking devices emit signals and sit outside the cloaked object.




The new studies are numerical and theoretical, and show how the cloaking method can work. "The research simulates on a computer what you should see in an experiment," Milton says. "We just do the math and hope other people do the experiments."

The Physical Review Letters study demonstrates the new cloaking method at a single frequency of electromagnetic waves, while the Optics Express paper demonstrates how it can work broadband, or at a wide range of frequencies.

In Optics Express, the mathematicians demonstrate that three cloaking devices together create a "quiet zone" so that "objects placed within this region are virtually invisible" to incoming waves.

[ObedientiaZelum]

NDHQ would be the biggest buyer.

[Thucydides]

Advancing the art:

http://nextbigfuture.com/2010/03/three-dimensional-invisibility-cloak-at.html

Three-Dimensional Invisibility Cloak at Optical Wavelengths

    A three-dimensional invisibility-cloaking structure operating at optical wavelengths based on transformation optics has been designed and realized. Our blueprint uses a woodpile photonic crystal with tailored polymer filling fraction to hide a bump in a gold reflector. Structures and controls are fabricated by direct laser writing and characterized by simultaneous high-numerical-aperture far-field optical microscopy and spectroscopy. Cloaking operation with large bandwidth of unpolarized light from 1.4- to 2.7-µm wavelength is demonstrated for viewing angles up to 60 degrees

Beyond military applications, cloaking devices are drawing interest from telecommunications companies, who see them as a way to send information by light more efficiently. One idea is to use the new materials to build "superantennas" that can concentrate light and other electromagnetic waves to make laser-like beams.

From physorg,

    the cloak is a structure of crystals with air spaces in between, sort of like a woodpile, that bends light, hiding the bump in the gold later beneath, the researchers reported in Thursday's online edition of the journal Science.

    In this case, the bump was tiny, a mere 0.00004 inch high and 0.0005 inch across (100 microns x 30 microns), so that a magnifying lens was needed to see it.

    "In principle, the cloak design is completely scalable; there is no limit to it," Ergin said. But, he added, developing a cloak to hide something takes a long time, "so cloaking larger items with that technology is not really feasible."

    "Other fabrication techniques, though, might lead to larger cloaks," he added in an interview via e-mail.

    The value of the finding, Ergin said, "is that we learn more about the concepts of transformation optics, and that we have made a first step in producing 3-D structures in that field."

    Guardian UK - Tolga Ergin and Nicolas Stenger at the Karlsruhe Institute of Technology in Germany used a technique called direct laser writing lithography to create a sheet of cloaking material from tiny plastic rods. The spacing of the rods, each of which measured one thousandth of a millimetre wide, alters a property of the material known as the refractive index, which changes the speed of light inside it.

    The researchers placed a piece of the material over a dimple in a gold sheet and used infrared cameras to see what happened. When the cloak was in place, it altered the speed of light around the bump in such a way that the gold sheet appeared to be flat. The experiment was equivalent to hiding something under a carpet and having the carpet disappear too.

    It is the first time researchers have demonstrated a cloak that works in three dimensions. Previous devices have hidden objects when looked at head-on, but did not work if viewed from the side. "We were surprised that the cloaking effect was still so good, Ergin told the US journal, Science.

    Inside the material, the plastic rods are arranged like planks of wood piled up on each other. The high precision of the structure means it is possible to control the refractive index so it varies in just the right way to bend light around whatever object is hidden beneath it.

    "The material has a higher refractive index on top of the bump, so light hitting that part is slowed down a little bit compared with light impinging on the rest of the surface," said Stenger. "That compensates for the shape of the bump, and in the end, it is exactly as if there was no bump."

    Research into cloaking devices has attracted funding from military organisations, such as the US Defence Advanced Research Projects Agency, which backs high-risk science research for the Pentagon. In the near term, cloaking materials are expected to be used to hide aircraft from radar more effectively.

[Thucydides]

And now using metamaterials on the offense:

http://nextbigfuture.com/2010/04/sound-bullets-generated-by.html

Sound Bullets Generated by Metamaterials for Killing Cancer Tumors or Submarines

PNAS - Generation and control of sound bullets with a nonlinear acoustic lens

    Acoustic lenses are employed in a variety of applications, from biomedical imaging and surgery to defense systems and damage detection in materials. Focused acoustic signals, for example, enable ultrasonic transducers to image the interior of the human body. Currently however the performance of acoustic devices is limited by their linear operational envelope, which implies relatively inaccurate focusing and low focal power. Here we show a dramatic focusing effect and the generation of compact acoustic pulses (sound bullets) in solid and fluid media, with energies orders of magnitude greater than previously achievable. This focusing is made possible by a tunable, nonlinear acoustic lens, which consists of ordered arrays of granular chains. The amplitude, size, and location of the sound bullets can be controlled by varying the static precompression of the chains. Theory and numerical simulations demonstrate the focusing effect, and photoelasticity experiments corroborate it. Our nonlinear lens permits a qualitatively new way of generating high-energy acoustic pulses, which may improve imaging capabilities through increased accuracy and signal-to-noise ratios and may lead to more effective nonintrusive scalpels, for example, for cancer treatment.


Discovery News has coverage

    The simple set up belies the power of the new metamaterial. Not only did the scientists focus all of the sound waves onto one specific area; they also amplified those waves more than 100 times than what any other metamaterial had previously produced. Those numbers could easily go higher, said Daraio.

    The sound waves Daraio and Spadonia manipulated were too high pitched for human ears to detect. Properly adapted to audible sound, the new metamaterial could turn a normal sentence into a split second ear drum rupturing explosion.

    If these sound bullets were actual bullets, the metamaterial would be like transforming hot lead projectiles into rocket propelled grenades, all converging on one place at one time. The damage such concentrated waves of pressure could create would be devastating.

    Like normal bullets, sound bullets can travel through air. Unlike normal bullets, sound bullets can also easily travel through liquids and solids. Sound bullets could be used by the military to create submarine melting waves of pressure or shock waves powerful enough to destroy caves otherwise untouchable by conventional weapons.

    The beauty of this system is that it’s just a bunch of ball bearings that we control with weights,” said Chiara Daraio, a member of the research team. Caltech’s acoustic lens relies on the same principle as Newton’s cradle-that toy your high school science teacher probably kept on his or her desk with metal balls on strings that demonstrated the conservation of energy.

    In this design, 21 parallel chains each contain 21 bearings. When the team strikes one end, it starts a compression wave that carries through the system. But instead of having the last ball swing out like a pendulum and bring the momentum back into the system, like the toy does, the acoustic lens focuses all the energy at the end of the system onto one spot, just a few inches away from the metamaterial.

    The paper also hints at use in defense systems, though it leaves the implications of that to the imaginations of others. Sound bullets could be used by the military to create submarine melting waves of pressure or shock waves powerful enough to destroy caves otherwise untouchable by conventional weapons.

[GAP]

Invisible Tanks, Planes and Armor Could Hit Battlefields in 5 Years
Article Link
Published January 18, 2011

Invisible tanks -- and maybe invisible soldiers -- may soon be charging onto battlefields.

A British weapons manufacturer is making good on the promise of Wonder Woman's invisible jet, describing an "eCamouflage" system that uses electronic ink to disguise combat vehicles by projecting videos of the countryside onto them -- electronic squid ink of a sort.

Using highly sophisticated electronic sensors attached to a vehicle's hull, BAE Systems plans to project images of the surrounding environment back onto the outside of the vehicle -- enabling it to merge into the landscape and evade attack, explained London paper The Telegraph.

Unlike conventional forms of camouflage, the images on the hull would change in concert with the changing environment, always insuring that the vehicle remains disguised.

BAE Systems is working with an unnamed Swedish company that makes a technology similar to the e-ink screens in digital book readers like the Amazon Kindle and Sony Reader, explained Mike Sweeney, head of external communications for the company.

E-ink screens, as any e-book reader can attest, are both slow to refresh and black and white -- two clear obstacles to this technology. BAE has solved those problems, Sweeney told FoxNews.com.

"The guys in Sweden, together with some other companies we've been looking at, have the answer to that question," he said. BAE is starting with tanks, such as the CV90 (or Combat Vehicle 90, the Swedish equivalent of the Bradley tank) on which the first tests will be conducted. But the technology won't be limited to them, Sweeney said.

"We're also working on it for aircraft," he told FoxNews.com.

This isn't the first time the technology has been discussed. FoxNews.com wrote about invisible tanks in 2007, when they were merely a concept. And BAE isn't alone in its quest to make things vanish. Several companies have been working on similar technologies, all based on the same approach, as Sweeney was quick to note: They all use "a camera to capture the scene on the other side of the vehicle, then project that image on the other side of the vehicle so that it blends into the environment."

But BAE plans to make it happen, intending to test in Sweden at the end of the month a technology it calls "adaptive signature." And the next stage, Sweeney explained, will be transparent battle armor for soldiers.
More on link

[Avor]

A very intriguing prospect, but It's hard to imagine it fully intergrated. The cost aside, the practical issues of reliability,durability and maintaince need to be adressed.

[57Chevy]

Like it was taken right out of the movie "Predator" with Arnold....
Check out this video entitled Optical camouflage for military troops
also this other one entitled Soldier using invisibilty cloak. (Army optical camouflage technology).

A few others at either link.
                                     (Reproduced under the Fair Dealings provisions of the Copyright Act)

[dogger1936]

Until the troops hook up their playstations to the invisiable lav to have a 5 on 5 game in the Argandab

[E.R. Campbell]

Technologies of this sort are under development in several places, I think; search here, on Army.ca, for something like "invisibility cloaks." The ideas of stealth and visual deception are attractive - to soldiers who, correctly, value security and surprise, and to vendors who value profits.
 

[milnews.ca]

Invisible Tanks, Planes and Armor Could Hit Battlefields in 5 Years
Article Link
Published January 18, 2011

Invisible tanks -- and maybe invisible soldiers -- may soon be charging onto battlefields ....

If they ARE truly invisible, how would we know?

[SherH2A]

metal, noise, heat, motion detectors. How is it different from detecting submarines?

Invisibility cloaks for tanks etc. are not the endall or be all, good troopes used to thinking for themselves will see things like trails being left in snow or sand. It's just another tool in the soldier's arsenal like a ghilly suit.

But it sure looks neat

[Thucydides]

A different form of "invisibility" is produced through the use of metamaterials (the subject of threads on invisibility cloaks), which have freaky optical properties to redirect waves of light or RF energy around an object, so it effectively does not exist to whoever is looking at it. "Full spectrum" metamaterials do not exist yet, but even eliminating the signature at a particular wavelength would be very disconcerting (the beam from a laser designator is directed around the object, giving you no return, for example. A visible object cloaked in the infra red wavelengths would become invisible to Thermal Imagers and sensors based on that effect).

As noted, the game of offense and defense is ongoing. For anyone who remembers the movie "Quest for Fire", the one group of cavemen hijack the newly returned fire, and one throws a spear to ensure the heroes of the film are out of range. In reply, the intrepid explorers (who found and returned the fire in the first place) fix arrow sized projectiles to Atlatls and shower the hijackers with something resembling an arrow storm, killing them all and allowing the heroes to recover the fire. The arms race dates back to the stone age, and possibly earlier...

[jollyjacktar]

Shared with the usual caveats.  http://www.aolnews.com/2011/01/27/squid-may-help-make-soldiers-invisible/

Squid May Help Make Soldiers Invisible

For decades, military scientists have tried to figure out the best way to make things disappear, or at least hide them very well.  Members of the U.S. Army's First Earth Battalion hoped to bend physics and render themselves invisible, when they weren't trying to kill goats by staring at them. The British Ministry of Defense's Future Protected Vehicle project wants top tech companies to create an invisible tank, possibly using cameras and reflective screens, to use for patrols in Afghanistan.

But researchers working for the U.S. Navy have found a more down-to-earth -- down-to-sea, in fact -- inspiration in the search for stealth: squid.  Yes, those gentle sea creatures, tasty when deep-fried and served with a piquant marinara sauce, figure prominently in the quest for a real-life cloaking device.  Scientists at Duke University -- something of a hotbed for this kind of work over the years -- the Scripps Institute of Oceanography and the University of California, Santa Barbara's Marine Science Institute are studying the mechanics of how squid, cuttlefish and octopus use special light-sensitive organs and cells to manipulate light and create "dynamic camouflage."

What does that mean? If you've ever gone scuba diving and encountered a cuttlefish, you may have noticed its ability to change color while matching its surroundings, even while jetting along in the water. Its cousin the octopus can even use muscles in its skin to imitate textures, to appear like algae or a rough ocean-reef rock. These chameleons of the sea, called cephalopods, create a range of special effects not just for hiding, but for attracting mates and catching prey.

Cephalopods cast their illusions primarily with organs called chromatophores -- tiny ink sacs controlled by muscles that release pigments in patterns, in layers under the skin. They are among the most intelligent creatures in the sea, and their pattern-making is so advanced they could "probably play a television show on their backs, if their brains were big enough," says Sonke Johnsen, associate professor of biology at Duke University.  "They make color sort of the way soap bubbles do ... but the neat thing about it is they can actively control it."

With $5 million in funding from the U.S. Navy over the next five years, Johnsen is leading a team of researchers trying to determine, in part, whether dynamic camouflage can be put to use on the battlefield.  "The systems evolved by marine animals in order to hunt, hide and mate over hundreds of million years surpass our contemporary engineering designs for underwater vehicles," says one of the team's studies. "The impact will hopefully affect all branches of the armed forces that have aquatic missions. This includes Special Forces, mine hunting vehicles, the submarine community and a newest generation of underwater vehicles that could all benefit from the option of 'stealth.'"

Not just the Navy is interested, either. The Army; defense contractor Raytheon; and the Pentagon's deep-science think tank, the Defense Advanced Research Projects Agency, have funded or are otherwise also involved in the team's work.  They call their primary research tool a Holodeck. But don't think of it in terms of creating Cmdr. Riker-style fantasies -- this Holodeck is about making the animals feel at home.  "We are able to show the animals any scene we want. We have a camera called an Omnicam that takes pictures in all six directions," Johnsen says.  Six monitors -- in essence, plasma-screen TVs -- surround the Holodeck tank, so the team can create a "fairly seamless representation of the world, like being on a coral reef," says Johnsen.  With scientists studying a variety of ways to achieve invisibility, or at least creating the illusion of it, could cephalopods provide the breakthrough? Think twice before ordering that plate of calamari.  "At the moment, what we are left with are the tricks that animals use," Johnsen says. "They are not true invisibility, but they are very good."


Here is a video from the article showing what they mean, it's fantastic.  http://www.youtube.com/watch?feature=player_embedded&v=7NQUqR_YpsA

[Thucydides]

All aspect invisibility is becoming closer to reality:

http://nextbigfuture.com/2011/08/invisibility-cloaking-for-whole.html

Invisibility cloaking for the whole spectrum

A light trajectory is shown against the distribution of the εσ values. The light ray enters the device, completes a loop, bounces off the mirror twice and leaves the cloak with its original direction restored (A). Panel (B) gives a closer view of the vicinity of the inner branch of the cloak. Objects placed within the white region are invisible.

An undergraduate student has overcome a major hurdle in the development of invisibility cloaks by adding an optical device into their design that not only remains invisible itself, but also has the ability to slow down light.

The optical device, known as an 'invisible sphere', would slow down all of the light that approaches a potential cloak, meaning that the light rays would not need to be accelerated around the cloaked objects at great speeds ― a requirement that has limited invisibility cloaks to work only in a specified region of the visible spectrum.

This new research, published today, Tuesday 9 August, in the Institute of Physics and German Physical Society's New Journal of Physics, could open up the possibility for a potential invisibility cloak wearer to move around amongst ever-changing backgrounds of a variety of colours.



New Journal of Physics - Invisibility cloaking without superluminal propagation

    Conventional cloaking based on Euclidean transformation optics requires that the speed of light should tend to infinity on the inner surface of the cloak. Non-Euclidean cloaking still needs media with superluminal propagation. Here we show by giving an example that this is no longer necessary.

    In this paper, we give an example of a device that achieves complete electromagnetic cloaking—not just `carpet cloaking'—while all light velocities within the cloak are finite and less than the speed of light. Through this example, we demonstrate that invisibility cloaking is possible without superluminal propagation and anomalous material requirements.

    The usual approach to designing an invisibility cloak works on the basis of bending light ― using highly specific materials ― around an object that you wish to conceal, thereby preventing the light from hitting the object and revealing its presence to the eye of the observer.

    When the light is bent, it engulfs the object, much like water covering a rock sitting in a river bed, and carries on its path making it seem as if nothing is there.

    Light, however, can only be accelerated to a speed faster than it would travel in space under certain conditions, and this restricts invisibility cloaks to work in a limited part of the spectrum ― essentially just one colour.

    This would be ideal if somebody was planning to stand still in camouflage; however, the moment that they start to move the scenery will begin to distort, revealing the person under the cloak.

    By slowing all of the light down with an invisible sphere, it does not need to be accelerated to such high speeds and can therefore work in all parts of the spectrum.

    Perczel said, "I started to work on the problem of superluminal propagation as Professor Leonhardt's summer student with an EPSRC grant. Once the idea was present, I worked for over eight months to overcome the technical barriers and to make the proposal practicable."

    An Institute of Physics spokesperson said, "This new development opens up further possibilities for the design of a practical invisibility cloak ― overcoming the problem of light speed that other advances have struggled to address and, very impressively, this significant advance was achieved by an undergraduate student."

[GR66]

Rather than starting a new thread...

The Americans obviously are not the only ones following this path.

From the BBC website today (Shared with the usual caveats):  http://www.bbc.co.uk/news/technology-14788009

This technology looks pretty impressive.  I'm sure it's pretty darned expensive and I'd imagine it may not be very robust in combat operations.  Rather than using this technology on a large scale to hide an armoured squadron I'd picture it being more cost effective to be used by recce specialty vehicles to target an enemy with stand-off weapons.  You'd need fewer vehicles and they would not be given away once they start firing their own weapons.



Edited to prevent my civilian ignorance from starting a debate about who has the role of calling in air/artillery/other types of beyond-line-of-sight attacks.

[dogger1936]

if I ever get one I'm gonna tape some untasteful things to the small camera to project all over my vehicle. Great tech; and I cannot wait to trial it one day!!

[Jim Seggie]

I am looking forward to the day the Stealth Blue Rocket is invented.

[cupper]

According to some conspiracy theory advocates, the technology has been in use for years now.

Opps, I've said too much, gotta go, the black helos are here.

[Spectrum]

According to some conspiracy theory advocates, the technology has been in use for years now.

Opps, I've said too much, gotta go, the black helos are here.

I'm pretty sure we already have the technology in the CF. We have loads of AFVs, helicopters, ships and soldiers....you just can't see them!

[FlyingDutchman]

The Sargent is watching you procastinate.

[1984]

Further development on the concept of an invisibility cloak by "slowing light":

http://www.canada.com/technology/Pentagon%2Bbacked%2Btime%2Bcloak%2Bstops%2Bclock/5946206/story.html

[Pistos]

Not to be confused with technologies to cloak objects in the infra-red spectrum:
http://www.wired.com/dangerroom/2011/09/invisibility-cloak-tanks-cows/?utm_source=Contextly&utm_medium=RelatedLinks&utm_campaign=Previous

...or technology to cloak objects in the visible light spectrum, aka mirage cloaking:
http://www.wired.com/dangerroom/2011/10/invisibility-cloak-mirage/

I can see future armor combining several upcoming technologies to shield us from prying eyes, and electronic detection.  Starcraft 'ghost' unit anyone? 

[Thucydides]

Should be joined to this thread: Metamaterials: a real invisibility cloak http://forums.army.ca/forums/index.php/topic,50470.msg446595.html#msg446595

[Colin P]

Bah, that's nothing, I have known several Gunners and Bombadiers that perfected vanishing to an art form, You would see them in the morning and then at the end of the day.

[1984]

Should be joined to this thread: Metamaterials: a real invisibility cloak http://forums.army.ca/forums/index.php/topic,50470.msg446595.html#msg446595

Agreed.  One stop shopping for all things invisible (a serious conversation on my work ethic could fit in here).  As an aside, your original thread didn't pop up on my search for 'cloaking device'.

[Thucydides]

Further advances in cloaking technologies:

http://iopscience.iop.org/1367-2630/14/1/013054/pdf/1367-2630_14_1_013054.pdf

http://nextbigfuture.com/2012/01/experimental-verification-of-three.html

Three-dimensional plasmonic cloak hides a cylinder from microwaves
Share
 
 New Journal of Physics - Experimental verification of three-dimensional plasmonic cloaking in free-space (14 pages) They optimized the cloak design for the 3 GHz range. They have hidden a cylinder from microwaves, demonstrating cloaking of an object in free space, rather than a two-dimensional image. The group has not been able to scatter visible light, but it expects that cloaking small objects is possible. The results pave the way to realistic, practical applications of 3D stand-alone cloaks for radar evasion and non-invasive radio frequency probing.

BBC News - The approach used is unlikely to work at the visible light part of the spectrum. Prof Alu explained that the approach could be applied to the tips of scanning microscopes - the most high-resolution microscopes science has - to yield an improved view of even smaller wavelengths of light.

In future applications, plasmonic materials could be combined with the structured metamaterials idea already in development elsewhere. Light can be channelled where it needs to go, or its effects undone, as need be.

Prof Apu said that if he had to bet in five years what kind of cloaking technique might be used for applications, for practical purposes, then he would say plasmonic cloaking is a good bet.

We report the experimental verification of metamaterial cloaking for a 3D object in free space. We apply the plasmonic cloaking technique, based on scattering cancellation, to suppress microwave scattering from a finite-length dielectric cylinder. We verify that scattering suppression is obtained all around the object in the near- and far-field and for different incidence angles, validating our measurements with analytical results and full-wave simulations. Our nearfield and far-field measurements confirm that realistic and robust plasmonic metamaterial cloaks may be realized for elongated 3D objects with moderate transverse cross-section at microwave frequencies.

[milnews.ca]

All the invisibility posts are now here, merged.

Milnet.ca Staff

[Jim Seggie]

Bah, that's nothing, I have known several Gunners and Bombadiers that perfected vanishing to an art form, You would see them in the morning and then at the end of the day.

Same for some officers.

[cupper]

All the invisibility posts are now here, merged.

Milnet.ca Staff

If they are invisible, how are we going to read them?

[Thucydides]

Low cost metamaterials are within reach. Once it becomes practical to make this in bulk many exciting possibilities open up:

http://oregonstate.edu/ua/ncs/archives/2012/feb/discovery-opens-avenue-“negative-refraction”-new-products-and-industries

“NEGATIVE REFRACTION” OPENS AVENUE TO NEW PRODUCTS AND INDUSTRIES

CORVALLIS, Ore. – Researchers at Oregon State University have discovered a way to make a low-cost material that might accomplish negative refraction of light and other radiation – a goal first theorized in 1861 by a giant of science, Scottish physicist James Maxwell, that has still eluded wide practical use.

Other materials can do this but they are based on costly, complex crystalline materials. A low-cost way that yields the same result will have extraordinary possibilities, experts say – ranging from a “super lens” to energy harvesting, machine vision or “stealth” coatings for seeming invisibility.

Entire new products and industries could be possible. The findings have just been published and a patent has been applied for on the technology.

The new approach uses ultra-thin, ultra-smooth, all-amorphous laminates, essentially a layered glass that has no crystal structure. It is, the researchers say, a “very high-tech sandwich.”

The goal is to make radiation bend opposite to the way it does when passing through any naturally occurring material. This is possible in theory, as Maxwell penciled out during the American Civil War. In reality, it’s been pretty difficult to do.

“To accomplish the task of negative refraction, these metamaterials have to be absolutely perfect, just flawless,” said Bill Cowell, a doctoral candidate in the OSU School of Electrical Engineering and Computer Science. “Everyone thought the only way to do that was with perfectly crystalline materials, which are quite expensive to produce and aren’t very practical for large-area commercial application.

“We now know these materials may not need to be that exotic.”

The new study has explained how easy-to-produce laminate materials, created with technology similar to that used to produce a flat panel television, should work for this purpose. The findings outline the component materials and the theoretical behavior of the laminates, Cowell said. They were just published in Physica Status Solidi A, in work supported by the National Science Foundation.

“We haven’t yet used this approach to achieve negative refraction, but the findings suggest it should work for that,” he said. “That will be one goal of continuing research. No one had thought of using amorphous metals for this purpose. They didn’t think it could be that simple.”

Negative refraction, Cowell said, is a brilliant idea. It is based on the equations developed by the young physicist and mathematician Maxwell more than 150 years ago – work for which he is revered, along with Isaac Newton and Albert Einstein, as one of the greatest physicists who ever lived. Einstein kept a photograph of Maxwell on his office wall.

But for generations, theory is about all that it was. Just in the past decade have researchers finally figured out how to create materials of any type that can achieve negative refraction. A way to accomplish that at low cost for the commercial marketplace could be of considerable importance, scientists say.

One application of particular interest is a “super lens,” a device that might provide light magnification at levels that dwarf any existing technology. Many applications are possible in electronics manufacturing, lithography, biomedicine, insulating coatings, heat transfer, space applications, and perhaps new approaches to optical computing and energy harvesting.

The discovery of amorphous metamaterials is an outgrowth of recent findings at OSU about ways to create a metal-insulator-metal, or MIM diode, also of commercial significance. The OSU research is one of the latest advances in “dispersion engineering,” or the control of electromagnetic radiation.

About the OSU College of Engineering: The OSU College of Engineering is among the nation’s largest and most productive engineering programs. In the past six years, the College has more than doubled its research expenditures to $27.5 million by emphasizing highly collaborative research that solves global problems, spins out new companies, and produces opportunity for students through hands-on learning.

The "other" applications of metamaterials such as super lenses and energy harvesting have applications on the military side as well; high power optics that are much smaller and lighter than existing ones, and the ability to concentrate solar energy to make small man portable collectors that can generate useful amounts of energy when the sun is shining come to mind.