UK firm developing laser bomb detectors for NATO troops to neutralize �invisible� Taliban bombs

May 15, 2010 By Leave a Comment

London, May 15 (ANI): NATO Commanders, and the US in particular, have reportedly accepted a revolutionary new laser technology developed by a company in Britain that can detect Taliban explosives with negligible quantities of metal or even devoid of metal.

The Taliban have reportedly begun constructing �invisible� bombs.

The Times quoted Don Arnone, chief executive of the Cambridge-based TeraView, as saying that the US Defense Department has already evaluated his company�s technology, which has been developed with funding from the British Home Office.

NATO commanders have said that they want to sponsor a trial in August, while government agencies in Britain are also interested.

�With the Terahertz laser you can actually penetrate clothes, packages and identify the content,� Arnone said.

The device operates on the principle of light waves and differing wavelengths.

The technology works by passing a Terahertz light, which lies between radio and light waves in the electromagnetic spectrum, through an explosive. The way in which the light is absorbed signals whether it contains explosives.

Arnone believes that with sufficient investment, his company�s technology, called the Terahertz Standoff Explosives Detection Unit, could be adapted for use on the front line within 18 months to two years.

At the moment the device is the size of a photocopier, and therefore, needs to be modified to make it more mobile for troops.

The only limitation of the device is its inability to detect metal. This means troops will have to continue using metal detectors. (ANI)

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Harry Potter’s invisibility cloak created in 3D

March 19, 2010 By Leave a Comment

Washington, Mar 19 (ANI): The magical cloak that featured in the Harry Potter series has become closer to reality, thanks to German scientists who’ve created a three-dimensional “invisibility cloak” that can hide objects by bending light waves.

Scientists from Karlsruhe Institute of Technology in Germany and Imperial College London reported their discovery in the journal Science.

The boffins used their cloak, made using photonic crystals with a structure resembling piles of wood, to conceal a small bump on a gold surface, reports Discovery News.

“It”s kind of like hiding a small object underneath a carpet — except this time the carpet also disappears,” they said.

“We put an object under a microscopic structure, a little like a reflective carpet,” said Nicholas Stenger, one of the researchers who worked on the project.

“When we looked at it through a lens and did spectroscopy, no matter what angle we looked at the object from, we saw nothing. The bump became invisible,” said Stenger.

The “cloak” hid an object from detection using light of wavelengths close to those that are visible to humans.

Now, the boffins are working to recreate the disappearing bump but on a larger scale.

Stenger said: “Theoretically, it would be possible to do this on a large scale but technically, it”s totally impossible with the knowledge we have now.” (ANI)

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‘Invisibility cloak’ metamaterials could shrink cellphones antennas

August 22, 2009 By Leave a Comment

London, Aug 22 (ANI): An international team of physicists have revealed that metamaterials, which are currently being used to make real-life invisibility cloaks, may soon shrink cellphone antennas, leading to smaller gadgets.

The new metamaterial antennas could be tuned to a range of different frequencies as required.

It could be tuned to work efficiently across a small frequency range, and retuned to a different band for roaming.

Tom Driscoll at the University of California, San Diego along with Dimitri Basov and collaboraters from Duke University in Durham, North Carolina, and ETRI in the Republic of Korea developed the new “frequency-agile” design by attaching a thin film of vanadium dioxide to a gold metamaterial structure.

They found that applying a voltage to the film alters the frequency at which the gold metamaterial interferes with light waves, tuning it to a new “setting”.

This occurs because voltage causes nanoscale “puddles” of conducting vanadium metal to form within the insulating vanadium dioxide.

They interact with the design’s electrical properties and alter the metamaterial’s tuning.

“The effect continues after the electrical current is gone because the metal puddles, once formed, will not readily disappear without some cause,” New Scientist quoted Driscoll as saying

He added that there is evidence to suggest the effect should last for months or more.

“Metamaterials are often narrowband, but at least with this scheme one could adapt the material to new frequencies,” said Ulf Leonhardt, a metamaterial researcher at the University of St Andrews in the UK.

That removes an obstacle to the wider use of metamaterial antennas. Such antennas would be attractive because they could help to shrink the size of cellphones.

Driscoll said that a tunable metamaterial antenna would allow a wireless gadget to work “outstandingly well” at the frequencies used in one country, but also carry the option of retuning for use abroad.

The findings appear in journal Science Express. (ANI)

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Harry Potter’s invisibility cloak could be a reality in two years

August 21, 2009 By Leave a Comment

London, Aug 21 (ANI): A University of St Andrews scientist has made fresh advancement in bringing Harry Potter’s invisibility cloak closer to reality.

Professor Ulf Leonhardt, who has won funding to develop a real version of the magical device, describes his work as the “ultimate optical illusion’.

He is planning to use refractive metals to make light waves flow around an object, as happens in a mirage, when blue light from the sky is bent by heated air to create the impression of a blue pond in the desert.

Pushing the laws of refraction and reflection to the limit, he plans an extreme version of the affect that appears while watching a fish in a glass tank.

The deflection of light as it moves from the air to the glass to the water makes the fish seem bigger and in a different part of the tank that in reality.

“Imagine a transparent material that guides light around an object without distorting the light – the object would disappear from view,” the Telegraph quoted Leonhardt as saying.

“I will most certainly find easier ways of cloaking, but it remains to be seen how practical they are.

“The important thing is to understand the foundations and come up with something new or take an existing idea to extremes; using technology and ideas to make things happen – technology we cannot imagine would ever exist,” he added.

The physicist has won funding from the Royal Society’s Theo Murphy Blue Skies award worth 100,000 pounds, so he will be able to pursue full time his invisible project for the next two years. (ANI)

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Scientists explain how maths can bring invisibility cloak closer to reality

March 6, 2009 By Leave a Comment

Washington, Mar 6 (ANI): Harry Potter’s invisibility cloak may have intrigued many of J.K. Rowling’s fans, and now researchers have come a step closer to realising it, by explaining how mathematics can turn out to be a major tool in the developing field of cloaking.

Ranked the number five breakthrough of the year by Science magazine in 2006, cloaking involves making an object invisible or undetectable to electromagnetic waves.

And now scientists have presented a paper giving an overview of the theoretical developments in cloaking from a mathematical perspective.

One method involves light waves bending around a region or object and emerging on the other side, as if the waves had passed through empty space, creating an “invisible” region that is cloaked.

But for that, the object or region has to be concealed using a cloaking device, which must be undetectable to electromagnetic waves.

Manmade devices called metamaterials use structures having cellular architectures designed to create combinations of material parameters not available in nature.

Mathematics is essential in designing the parameters needed to create metamaterials, and to show that the material ensures invisibility.

The mathematics comes primarily from the field of partial differential equations, in particular from the study of equations for electromagnetic waves described by the Scottish mathematician and physicist James Maxwell in the 1860s.

One of the “wrinkles” in the mathematical model of cloaking is that the transformations that define the required material parameters have singularities, that is, points at which the transformations fail to exist or fail to have properties such as smoothness or boundness that are required to demonstrate cloaking.

But the singularities are removable, which means that the transformations can be redefined over the singularities to obtain the desired results. The authors of the paper describe this as “blowing up a point”.

The paper also suggests that if there are singularities along a line segment, it is possible to “blow up a line segment” to generate a “wormhole”.

The cloaking version of a wormhole allows for an invisible tunnel between two points in space through which electromagnetic waves can be transmitted.

Cloaking via electromagnetic wormholes has many possible applications, which include the creation of invisible fibre optic cables, for example for security devices, and scopes for MRI-assisted medical procedures for which metal tools would otherwise interfere with the magnetic resonance images.

The invisible optical fibres could even make three-dimensional television screens possible in the distant future.

The paper titled ‘Cloaking Devices, Electromagnetic Wormholes, and Transformation Optics’, has been published in SIAM Review. (ANI)

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Scientists explain how maths can bring invisibility cloak closer to reality

March 6, 2009 By Leave a Comment

Washington, Mar 6 (ANI): Harry Potter’s invisibility cloak may have intrigued many of J.K. Rowling’s fans, and now researchers have come a step closer to realising it, by explaining how mathematics can turn out to be a major tool in the developing field of cloaking.

Ranked the number five breakthrough of the year by Science magazine in 2006, cloaking involves making an object invisible or undetectable to electromagnetic waves.

And now scientists have presented a paper giving an overview of the theoretical developments in cloaking from a mathematical perspective.

One method involves light waves bending around a region or object and emerging on the other side, as if the waves had passed through empty space, creating an “invisible” region that is cloaked.

But for that, the object or region has to be concealed using a cloaking device, which must be undetectable to electromagnetic waves.

Manmade devices called metamaterials use structures having cellular architectures designed to create combinations of material parameters not available in nature.

Mathematics is essential in designing the parameters needed to create metamaterials, and to show that the material ensures invisibility.

The mathematics comes primarily from the field of partial differential equations, in particular from the study of equations for electromagnetic waves described by the Scottish mathematician and physicist James Maxwell in the 1860s.

One of the “wrinkles” in the mathematical model of cloaking is that the transformations that define the required material parameters have singularities, that is, points at which the transformations fail to exist or fail to have properties such as smoothness or boundness that are required to demonstrate cloaking.

But the singularities are removable, which means that the transformations can be redefined over the singularities to obtain the desired results. The authors of the paper describe this as “blowing up a point”.

The paper also suggests that if there are singularities along a line segment, it is possible to “blow up a line segment” to generate a “wormhole”.

The cloaking version of a wormhole allows for an invisible tunnel between two points in space through which electromagnetic waves can be transmitted.

Cloaking via electromagnetic wormholes has many possible applications, which include the creation of invisible fibre optic cables, for example for security devices, and scopes for MRI-assisted medical procedures for which metal tools would otherwise interfere with the magnetic resonance images.

The invisible optical fibres could even make three-dimensional television screens possible in the distant future.

The paper titled ‘Cloaking Devices, Electromagnetic Wormholes, and Transformation Optics’, has been published in SIAM Review. (ANI)

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Scientists explain how maths can bring invisibility cloak closer to reality

March 6, 2009 By Leave a Comment

Washington, Mar 6 (ANI): Harry Potter’s invisibility cloak may have intrigued many of J.K. Rowling’s fans, and now researchers have come a step closer to realising it, by explaining how mathematics can turn out to be a major tool in the developing field of cloaking.

Ranked the number five breakthrough of the year by Science magazine in 2006, cloaking involves making an object invisible or undetectable to electromagnetic waves.

And now scientists have presented a paper giving an overview of the theoretical developments in cloaking from a mathematical perspective.

One method involves light waves bending around a region or object and emerging on the other side, as if the waves had passed through empty space, creating an “invisible” region that is cloaked.

But for that, the object or region has to be concealed using a cloaking device, which must be undetectable to electromagnetic waves.

Manmade devices called metamaterials use structures having cellular architectures designed to create combinations of material parameters not available in nature.

Mathematics is essential in designing the parameters needed to create metamaterials, and to show that the material ensures invisibility.

The mathematics comes primarily from the field of partial differential equations, in particular from the study of equations for electromagnetic waves described by the Scottish mathematician and physicist James Maxwell in the 1860s.

One of the “wrinkles” in the mathematical model of cloaking is that the transformations that define the required material parameters have singularities, that is, points at which the transformations fail to exist or fail to have properties such as smoothness or boundness that are required to demonstrate cloaking.

But the singularities are removable, which means that the transformations can be redefined over the singularities to obtain the desired results. The authors of the paper describe this as “blowing up a point”.

The paper also suggests that if there are singularities along a line segment, it is possible to “blow up a line segment” to generate a “wormhole”.

The cloaking version of a wormhole allows for an invisible tunnel between two points in space through which electromagnetic waves can be transmitted.

Cloaking via electromagnetic wormholes has many possible applications, which include the creation of invisible fibre optic cables, for example for security devices, and scopes for MRI-assisted medical procedures for which metal tools would otherwise interfere with the magnetic resonance images.

The invisible optical fibres could even make three-dimensional television screens possible in the distant future.

The paper titled ‘Cloaking Devices, Electromagnetic Wormholes, and Transformation Optics’, has been published in SIAM Review. (ANI)

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