Teh One Who Knocks
01-04-2012, 10:41 PM
Pentagon-supported physicists on Wednesday said they had devised a "time cloak" that briefly makes an event undetectable.
By SETH BORENSTEIN , AP Science Writer
http://i.imgur.com/aC7Yf.jpg
It's one thing to make an object invisible, like Harry Potter's mythical cloak. But scientists have made an entire event impossible to see. They have invented a time masker.
Think of it as an art heist that takes place before your eyes and surveillance cameras. You don't see the thief strolling into the museum, taking the painting down or walking away, but he did. It's not just that the thief is invisible - his whole activity is.
What scientists at Cornell University did was on a much smaller scale, both in terms of events and time. It happened so quickly that it's not even a blink of an eye. Their time cloak lasts an incredibly tiny fraction of a fraction of a second. They hid an event for 40 picoseconds (trillionths of a second), according to a study appearing in Thursday's edition of the journal Nature.
We see events happening as light from them reaches our eyes. Usually it's a continuous flow of light. In the new research, however, scientists were able to interrupt that flow for just an instant.
Other newly created invisibility cloaks fashioned by scientists move the light beams away in the traditional three dimensions. The Cornell team alters not where the light flows but how fast it moves, changing in the dimension of time, not space.
They tinkered with the speed of beams of light in a way that would make it appear to surveillance cameras or laser security beams that an event, such as an art heist, isn't happening.
Another way to think of it is as if scientists edited or erased a split second of history. It's as if you are watching a movie with a scene inserted that you don't see or notice. It's there in the movie, but it's not something you saw, said study co-author Moti Fridman, a physics researcher at Cornell.
The scientists created a lens of not just light, but time. Their method splits light, speeding up one part of light and slowing down another. It creates a gap and that gap is where an event is masked.
"You kind of create a hole in time where an event takes place," said study co-author Alexander Gaeta, director of Cornell's School of Applied and Engineering Physics. "You just don't know that anything ever happened."
This is all happening in beams of light that move too fast for the human eye to see. Using fiber optics, the hole in time is created as light moves along inside a fiber much thinner than a human hair. The scientists shoot the beam of light out, and then with other beams, they create a time lens that splits the light into two different speed beams that create the effect of invisibility by being too fast or too slow. The whole work is a mess of fibers on a long table and almost looks like a pile of spaghetti, Fridman said.
It is the first time that scientists have been able to mask an event in time, a concept only first theorized by Martin McCall, a professor of theoretical optics at Imperial College in London. Gaeta, Fridman and others at Cornell, who had already been working on time lenses, decided to see if they could do what McCall envisioned.
It only took a few months, a blink of an eye in scientific research time.
"It is significant because it opens up a whole new realm to ideas involving invisibility," McCall said.
Researchers at Duke University and in Germany's Karlsruhe Institute of Technology have made progress on making an object appear invisible spatially. The earlier invisibility cloak work bent light around an object in three dimensions.
Between those two approaches, the idea of invisibility will work its way into useful technology, predicts McCall, who wasn't part of either team.
The science is legitimate, but it's still only a fraction of a second, added City College of New York physicist Michio Kaku, who specializes in the physics of science fiction.
"That's not enough time to wander around Hogwarts," Kaku wrote in an email. "The next step therefore will be to increase this time interval, perhaps to a millionth of a second. So we see that there's a long way to go before we have true invisibility as seen in science fiction."
Gaeta said he thinks he can get make the cloak last a millionth of a second or maybe even a thousandth of a second. But McCall said the mathematics dictate that it would take too big a machine - about 18,600 miles long - to make the cloak last a full second.
"You have to start somewhere and this is a proof of concept," Gaeta said.
Still, there are practical applications, Gaeta and Fridman said. This is a way of adding a packet of information to high-speed data unseen without interrupting the flow of information. But that may not be a good thing if used for computer viruses, Fridman conceded.
There may be good uses of this technology, Gaeta said, but "for some reason people are more interested in the more illicit applications."
Fridman's work was part-supported by the Defense Advanced Research Project Agency, or DARPA, a Pentagon unit which develops futuristic technology that can have a military use. Its achievements include DARPANet, a predecessor of the Internet.
Now you detect it, now you don’t
A ‘time cloak’ that makes an event temporarily undetectable, albeit on the picosecond scale, is described in this week’s Nature. The work could represent a step towards the development of spatio-temporal cloaking.
Recent developments in spatial cloaking show that it is possible to hide an object by manipulating electromagnetic waves around it, creating a ‘hole in space’. Such devices currently have limited functionality. Here Moti Fridman and colleagues demonstrate that a related effect, temporal cloaking, can be achieved. They manage to create a ‘hole in time’ for around 40 trillionths of a second (40 picoseconds).
The fibre-based system steers light ‘around’ an event so that no evidence (a change in the temporal or spectral properties of the light beam) of the event is detectable, by speeding up and slowing down different parts of a light beam. This effect is achieved using a split time-lens that breaks light up into its slower (red) and faster (blue) components, thereby creating a tiny temporal gap.
By SETH BORENSTEIN , AP Science Writer
http://i.imgur.com/aC7Yf.jpg
It's one thing to make an object invisible, like Harry Potter's mythical cloak. But scientists have made an entire event impossible to see. They have invented a time masker.
Think of it as an art heist that takes place before your eyes and surveillance cameras. You don't see the thief strolling into the museum, taking the painting down or walking away, but he did. It's not just that the thief is invisible - his whole activity is.
What scientists at Cornell University did was on a much smaller scale, both in terms of events and time. It happened so quickly that it's not even a blink of an eye. Their time cloak lasts an incredibly tiny fraction of a fraction of a second. They hid an event for 40 picoseconds (trillionths of a second), according to a study appearing in Thursday's edition of the journal Nature.
We see events happening as light from them reaches our eyes. Usually it's a continuous flow of light. In the new research, however, scientists were able to interrupt that flow for just an instant.
Other newly created invisibility cloaks fashioned by scientists move the light beams away in the traditional three dimensions. The Cornell team alters not where the light flows but how fast it moves, changing in the dimension of time, not space.
They tinkered with the speed of beams of light in a way that would make it appear to surveillance cameras or laser security beams that an event, such as an art heist, isn't happening.
Another way to think of it is as if scientists edited or erased a split second of history. It's as if you are watching a movie with a scene inserted that you don't see or notice. It's there in the movie, but it's not something you saw, said study co-author Moti Fridman, a physics researcher at Cornell.
The scientists created a lens of not just light, but time. Their method splits light, speeding up one part of light and slowing down another. It creates a gap and that gap is where an event is masked.
"You kind of create a hole in time where an event takes place," said study co-author Alexander Gaeta, director of Cornell's School of Applied and Engineering Physics. "You just don't know that anything ever happened."
This is all happening in beams of light that move too fast for the human eye to see. Using fiber optics, the hole in time is created as light moves along inside a fiber much thinner than a human hair. The scientists shoot the beam of light out, and then with other beams, they create a time lens that splits the light into two different speed beams that create the effect of invisibility by being too fast or too slow. The whole work is a mess of fibers on a long table and almost looks like a pile of spaghetti, Fridman said.
It is the first time that scientists have been able to mask an event in time, a concept only first theorized by Martin McCall, a professor of theoretical optics at Imperial College in London. Gaeta, Fridman and others at Cornell, who had already been working on time lenses, decided to see if they could do what McCall envisioned.
It only took a few months, a blink of an eye in scientific research time.
"It is significant because it opens up a whole new realm to ideas involving invisibility," McCall said.
Researchers at Duke University and in Germany's Karlsruhe Institute of Technology have made progress on making an object appear invisible spatially. The earlier invisibility cloak work bent light around an object in three dimensions.
Between those two approaches, the idea of invisibility will work its way into useful technology, predicts McCall, who wasn't part of either team.
The science is legitimate, but it's still only a fraction of a second, added City College of New York physicist Michio Kaku, who specializes in the physics of science fiction.
"That's not enough time to wander around Hogwarts," Kaku wrote in an email. "The next step therefore will be to increase this time interval, perhaps to a millionth of a second. So we see that there's a long way to go before we have true invisibility as seen in science fiction."
Gaeta said he thinks he can get make the cloak last a millionth of a second or maybe even a thousandth of a second. But McCall said the mathematics dictate that it would take too big a machine - about 18,600 miles long - to make the cloak last a full second.
"You have to start somewhere and this is a proof of concept," Gaeta said.
Still, there are practical applications, Gaeta and Fridman said. This is a way of adding a packet of information to high-speed data unseen without interrupting the flow of information. But that may not be a good thing if used for computer viruses, Fridman conceded.
There may be good uses of this technology, Gaeta said, but "for some reason people are more interested in the more illicit applications."
Fridman's work was part-supported by the Defense Advanced Research Project Agency, or DARPA, a Pentagon unit which develops futuristic technology that can have a military use. Its achievements include DARPANet, a predecessor of the Internet.
Now you detect it, now you don’t
A ‘time cloak’ that makes an event temporarily undetectable, albeit on the picosecond scale, is described in this week’s Nature. The work could represent a step towards the development of spatio-temporal cloaking.
Recent developments in spatial cloaking show that it is possible to hide an object by manipulating electromagnetic waves around it, creating a ‘hole in space’. Such devices currently have limited functionality. Here Moti Fridman and colleagues demonstrate that a related effect, temporal cloaking, can be achieved. They manage to create a ‘hole in time’ for around 40 trillionths of a second (40 picoseconds).
The fibre-based system steers light ‘around’ an event so that no evidence (a change in the temporal or spectral properties of the light beam) of the event is detectable, by speeding up and slowing down different parts of a light beam. This effect is achieved using a split time-lens that breaks light up into its slower (red) and faster (blue) components, thereby creating a tiny temporal gap.