Posted on 07/25/2006 10:13:18 AM PDT by Ben Mugged
Physicist Costas Soukoulis and his research group at the U.S. Department of Energy's Ames Laboratory on the Iowa State University campus are having the time of their lives making light travel backwards at negative speeds that appear faster than the speed of light.
~snip~ This backward-bending characteristic of metamaterials allows enhanced resolution in optical lenses, which could potentially lead to the development of a flat superlens with the power to see inside a human cell and diagnose disease in a baby still in the womb.
~snip~ In addition, Soukoulis and his University of Karlsruhe colleagues have also shown that both the velocity of the individual wavelengths, called phase velocity, and the velocity of the wave packets, called group velocity, are both negative, which Soukoulis said accounts for the ability of negatively refracted light to seemingly defy Einstein's theory of relativity and move backwards faster than the speed of light.
Elaborating, Soukoulis said, "When we have a metamaterial with a negative index of refraction at 1.5 micrometers that can disperse, or separate a wave into spectral components with different wavelengths, we can tune our lasers to play a lot of games with light. We can have a wavepacket hit a slab of negative index material, appear on the right-hand side of the material and begin to flow backward before the original pulse enters the negative index medium."
Continuing, he explained that the pulse flowing backward also releases a forward pulse out the end of the medium, a situation that causes the pulse entering the front of the material appear to move out the back almost instantly.
"In this way, one can argue that that the wave packet travels with velocities much higher than the velocities of light," said Soukoulis.
(Excerpt) Read more at spacedaily.com ...
Pretty neat, if genuine.
Great, there go my 20+ years of research on the flux-capacitor.
THis is really cool stuff. The fact they've gotten the wavelength range into the NIR is very, very, very impressive! Up to this point, only microwaves have been thus manipulated. The concept of the actual mechanism isn't all that difficult. The metamaterial is constructed so that it has conducting loops and rods that interact with the oscillating electric and magnetic components of the light entering in the material. These interations essentially set up counter fields in the material so the permiability and permissivity are negative, but only while the light is in the material. And none of this violates relativity or anything like that. It's been a while since I read the papers on this subject, but the superlens functions because the optics are not diffraction limited and are not dependent on surface curvature.
But when you do mention a 'perfect reflecting surface' you are somewhat close. If the light is in a high refractive index and hits the side of this material, it will be completely reflected if you are above the critical angle. It's called internal reflection and is the principle behind light transmission in fiber optics, amongst other things.
Reflection is off the surface, refraction is through the surface. Snell's law applies to refraction, where the angle of the light beam changes as the light passes through the surface between two media of different indixes of refraction.
It is in the context of Total Internal Reflection (TIR) that I was staging my question. If you have a negative refraction indice what happens to TIR? In fibers this interaction is at the core to cladding interface and some of the power is lost each time a reflection happens. If the negative refraction indice is exactly right, the core to cladding interface becomes a perfect reflector and no loss can occur. This could result in a fiber that could carry light over extreme distances without loss.
In other words, there exist mediums such that the speed of light remains constant, but will stretch out the wavelength like a curved mirror, such that the ends will go faster than c during the stretching, but the overall speed remains c?
That's right. Separating the phenomenon of reflection from the conditions of total internal reflection: when the light is simply reflected it has nothing to do with the index of refraction. Usually some light is reflected and some is transmitted, but the reflected portion goes right back into the same index of refraction it came from, so Snell's law would not apply to that portion. When the angle of incidence is such that the angle of refraction puts the rest of the refracted beam back into the material, then all the light stays in the material. Bell labs had an optical device that could be used in optical computing that sent the beam exactly parallel to the surface, the critical angle, so all of it entered the substrate with no loss, no reflection.
A perfect vacuum supposedly does this, but any kind of glass will absorb some light proportionally to path length. Water does this, too, and the absorption depends on frequency. There could be materials that do not absorb light at all, but I don't know of any.
That is a good question. Since we are dealing with a negative refractive index material, that would not be the core material since it will always have a lower n than the cladding. However, in total internal reflection, the light beam never propagates in the rarer medium (i.e. cladding in this case). Propagation is entirely within the more optically dense material. What does penetrate into the cladding from the fiber is an evanescent field whose intensity drops exponentially from the interface. Putting a negative index in for the cladding doesn't significantly change the penetration depth. On that basis, energy loss could still occur in the rarer, negative index material so it would not be a perfect reflector. However, things do get interesting if a polarized beam were to be used in an internal reflection geometry. I just tried the basic equations for internal reflection and, with polarized light, I was getting negative penetration depths, but positive ones for unpolarized light. This suggests that the evanescent field is inverted for S and P polarizations. these are just some off the cuff calculations. Looking at the equations, the polarized expression has a n21 factor (which is negative for a negative refractive index material) but this factor is not included in the equation for the unpolarized case. It is also interesting that the critical angle for a negative refractive index material is also negative. I'm wondering what meaning this has. Total internal reflection should occur if you are greater than the critical angle. In all of these experiments, the light is entering from air (n~1) into a lower refractive index material (n~-1). Under such a case, the critical angle is near -90 degrees but, experimentally, the beam enters the metamaterial. Does anyone know if reflection from these surfaces was measured? Me thinks the equations I'm using need to be re-derived for this type of situation.
One more thought. To make these metamaterials, special structures in the amterial need to be assembled and the size of those structures are of similar magnitude to the wavelength of light used in the experiment. If that is the case, the structures need to be within the penetration depth of the evanescent wave, otherwise, the bulk properties of the media in which the structures are embedded will dominate the internal reflection characteristics. This would also mean that the choice of incidence angle would also be very important. There is some serious thesis material here if someone wants to develop the theory.
Don't need a movie for that. Happens to me all the time just riding down the interstate.
All I can tell you
is I can't see the results
of the lottery
on my notebook page
before the drawing happens
and before I write
the winning numbers
down on the page. When I see
the winning numbers
on my notebook page
before I write them there, THEN
I'll get excited.
Actually, the velocity of light in a medium is slower than c. Light is essentially a transverse propagating electromagnetic wave. Material is made of matter which has certain electromagnetic properties. Even in a non-absorbing medium, the light will experience the eletronic effects of being in this material. I know the physicists on this board will object, but the electronic environment acts as a sort of resistance (just an analogy) and that's were the role of permittivity and permeability come into play. Even though the speed of light is slower in a medium, no energy is lost. The photon has the same energy content. TO conserve energy, the wavelength of light decreases (i.e. increases frequency). The wavelength in a medium is the wavelength in a vacuum divided by the refractive index of the medium. When the light re-emerges from the medium, it's speed again become c and it's wavelength returns to that which it was before entering the medium.
Mark
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