Light Traveling at 38 Miles an Hour 156
You can't let so many people be misinformed. Please let them know:
The speed of light IN A VACUUM is the constant c.
Science has been able to slow light down for centuries by making it travel through a different medium. The speed of light in air is less than c. The speed of light in water or glass or plastic is less than c. This is what makes lenses work. (check your encyclopedia for more information)
The reason this is a breakthrough is simply because they've been able to slow light down to a much lower speed than anyone else has ever been able to do. They have not changed c, the speed of light in a vacuum. The beam of light is only slowed down when it's in the condensate. Once it leaves the condensate and is travelling through air again, it returns to a speed of 186,000 miles per second. This does not contradict any law of physics. "
Practical Uses? (Score:1)
I can see using the properties that we learn elsewhere, but don't expect to ever see slow light yourslef...:)
Why c is the max speed (Score:1)
Great Danes? (Score:1)
what?? (Score:1)
You aren't going to be able to control the speed of the sun's light.
You could set up lights in your room to come on at a set time in the morning, (if it were still dark outside). But that would not benefit from slow light either.. You would have to control the power going to the lighting fixture, not the speed at which the light eminating from the fixture would reach you.
Hahaha, If you can't be them, slow them down. (Score:1)
For years we have tried to come up with a way to travel faster than the speed of light, hehehe, could not do that so now we have just decided to slow light down. They even are going to try to slow it down slow enough that a turtle could out walk a beam of light.
That is funny.
On the cover of Nature also (Score:1)
Here's the URL
http://www.nature.com/cover/cover0218.html
Wow, this is cool. (Score:1)
No, the first poster was right. They cooled the tramsmitting medium such that the time between absorbsion/emmission was dramatically heightened. I look forward to seeing a video of this, personally.
Actually ... (Score:1)
This isn't a hard fact. There is a fringe branch of physics which is looking into *increasing* the "c" constant. The trick here is that a vacuum is devoid of matter, but not of energy ond forces; it is this which constrains the speed of light, and modifying the constraints may allow light to travel faster than the cvac.
In other words, the finality of the maximal speed of light is accepted generally, but not completely, and there is some evidence in favor of the vocal few.
interesting... (Score:1)
hmmm...that's very cool.
index of refraction less than one (Score:1)
The phase velocity is equal to the optical frequency divided by the magnitude of the wave vector (i.e., if optical freq. = omega & wave vector = k, vphase = omega/|k|. Remember omega and k from exp[ i ( omega t - k.r) ], the active ingredient in a wavefunction).
The group velocity is equal to the derivative of the optical frequency with respect to the magnitude of the wave vector.
Where the relationship between the optical frequency and the wave vector's magnitude isn't strictly linear, that's where the phase velocity and the group velocity differ.
Absolute Zero != atoms stop moving (Score:1)
There is a little problem - it's called zero point energy. This permeates all of space/time, and was predicted by the Dutch physicist Hendrik Casimir in 1948. It's existence has been experimentaly proven ( refer to "Physical Review Letters, vol 78, p 5 ") by Dr Lamoreaux at the Los Alamos labs back in 1997.
Zero point energy prevents any physical particle from ever being completly still. It's the residual energy left over from the Big-Bang. Acording to the American physicist Richard Fenyman, the ZPE content of a volume the size of a coffee cup would be sufficient to completly vaporise the Earths oceans.
ZPE manifests as the constant production of particle/anti-particle pairs, the duration of their existence being inversely proportional to their energy ( in accordance with the Heisenberg uncertainty principle ). This is the source of Hawkins radiation around black-holes and the main reason why cyrogenic preservation is limited to a few thousand years, even if you could get to absolute zero ( which the third law of thermodynamics says you can't ).
Memory? (Score:1)
--
subscription? (Score:1)
Does anyone have a url of a version of this which is freely viewed?
-herb
Hey Cool (Score:1)
Of course she is Danish :) (Score:1)
It should tell something, either about me or about the Danish media.
Is it slower or does it just bounce around more? (Score:1)
--
Timur "too sexy for my code" Tabi, timur@tabi.org, http://www.tabi.org
Light speed and refractive index (Score:1)
As others have noted, the speed of light in a non-vacuum medium is slower by a ratio known as the refractive index, which is less than 2.5 for most materials (I think diamond is 2.42 or something) and is exactly 1 in a vacuum. So, the real news story here is the creation of a material with a *huge* refractive index (which is really neat).
Depending on how you manipulate the equations, it *is* possible to have a refractive index less than 1 (and therefore a "speed of light" faster than in vacuum). These conditions can occur in an ionized gas, such as the layers of our atmosphere which bounce radio signals around the globe. However, it also turns out that you can't transmit any information through this medium faster than in vacuum, so it's really just a mathematical curiosity.
Light not constant? (Score:1)
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version 2.10a
None whatsoever; "E=mc^2" will continue to be a widely-parroted simplification of the more general definition of the total energy of a particle, (E^2) = (m0c^2)^2 + (pc)^2, where m0 is the particle's rest mass and p is its momentum, and c is the speed of light _in vacuum_ (which hasn't changed). This news story is about some unique optical properties of a new type of matter, but it doesn't affect electromagnetism or relativity theories.
E=mc^2 may have been a big deal back when the "wireless" and the "horseless carriage" were on the top of every geek's Christmas wish-list, but these days it's just a routine part of physics like Ohm's law (V=IR) is in electronics. It's not a big deal. The rest of Einstein's work is much more interesting (general relativity, stimulated emission (lasers), the photoelectric effect, etc).
"E=mc^2" may look good on a T-shirt, but apart from that there's little reason why this particular Thought McNugget deserves to be so widely quoted when so much more of the really interesting physics is completely ignored.
By the way, nuclear fission was observed in the lab by people like Otto Hahn, without the need for "E=mc^2" to explain where the energy came from. Nuclear bombs are just a matter of banging rocks together, once you have the right rocks - who cares if the total mass of the bomb fragments is slightly less after the blast? Your city still ends up as kitty litter thanks to the binding energy in the nucleus.
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Help! Too hard! Speed of light != constant? (Score:1)
Oh dear... I'm confused. I thought speed of light was a constant ( c )? Or is that speed of light in a vaccuum? So what's the speed of light in vaccuum compared to the speed of light in air or water, then?
Feel free to flame away, I have absolutely no clue what I'm talking about and would appreciate it if someone could explain it in armchair terms.
At least now I know what computer illiterates feel like when I talk to them.
(it ain't my fault, my physics teacher was too attractive for 16-year-old boys to actually pay attention to what she *said*
Danes are cool. If only they could ban kiddy porn! (Score:1)
1. Raping children, recording it, trying to squeese out as much money as possible.
2. Beeing a pedophile and arousing yourself with sexual images of children, not produced using real children.
For me, people can have whatever strange sexual ideas they like, as long as they don't hurt people by, say, raping them.
So, what should be outlawed is of course not 'child porn' (wich can, for example, be drawn or computer animated) but raping or otherwise hurting children.
(Unlike here in Sweden where we have a new law since 1999 outlawing even the owning of any kind of child porn. Oh, they are so stupid! And over half the 'liberal' party voted for it (twice) and the largest 'conservative' voted against it. Just shows (again) that all they care of is votes/money/power and that ideologies and morals definetly comes in second place. Sigh.)
Uh, heard of Special Relativity? (Score:1)
So much for the universal constant. (Score:1)
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Wow, this is cool. (Score:1)
Like, if they get it going really slow, what's that mean for going faster than light?
-- haaz, playing Lead into Gold today..
like sound in rail-track (Score:1)
anyway, speed of sound is greater in steel that in air, as light speed is slower in water than vaccum, etc.
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Slow Glass (Score:1)
had a book predicated on a material called slow
glass. Basically it took light years to travel
through the medium, so you took a piece of glass
set it somewhere scenic for a year or two and then
hung it on your wall and enjoyed the view for
the same couple of years. A few more orders of
magnitude and we will be there..
slow light (Score:1)
Night vision goggles? Sheya... (Score:1)
After reading about just how much work they went through to make a BEC (that's Bose-Enstien Condensate), they then suggest that this could be used for night vision goggles.
Does anyone else NOT want a substance at about a billionth of a degree kelvin near their head? This stuff makes liquid nitrogen look toasty by comparison.
BEC's have all kinds of "odd" properties that make them interesting, but I can't get excited about strapping one over my eyes. Call me silly, but that just strikes me as a Bad Idea.
If they can duplicate the same quantum states that allow this high index of refraction in something a little more stable, this could actually lead to something practical, but I'm not holding my breath.
Also of interest, someone used a BEC to create a coherent beam of matter. I don't remember the URL though.
So much for the universal constant. (Score:1)
It isn't that difficult to comprehend unless you try and understand how they are abosrbed and re-emitted. THen it gets trickier to explain in normal words.
Mass ammounts of energy... (Score:1)
Slow Glass (Score:1)
Atom/Matter Lasers using BECs (Score:1)
And the first commercial application will be.... (Score:1)
Practical Uses? (Score:1)
Is it slower or does it just bounce around more? (Score:1)
As a first approximation, what happens is that the light enters the material, is absorbed by an atom and then re-emitted after a tiny delay and in the same direction. It then gets absorbed by another atom, etc etc. The delay before being retransmitted is what causes the reduction in the speed of light.
Something similar to what you describe occurs in a translucent medium - here the photons are re-emitted in random directions (and after a longer delay), so they do indeed seem to bounce off the atoms.
Note that in a BEC, there's no such thing as "an atom", so the actual mechanism is almost certainly nasty enough to require a PhD to understand.
Light Capacitors? (Score:1)
Slow Glass (Score:1)
Maybe this hypothetical slowglass would make a great battery?
slow light (Score:1)
The higher the index (i.e. slower the speed of light) in a material, the thinner the lens. That's why I can get 1/8" thick polycarbonate lenses for my glasses that do the same job as 1/2" thick glass.
Spectral dispersion is a problem in this application, though... however, if you're doing spectroscopy, a high-dispersion prism is useful... so therefore spectroscopy may be one of the first applications of a condensate prism.
As for the capacitor issue - The permittivity (capacitance/thickness) of a material is established by the speed of propogation of an EM wave (e.g. light) through the material. So a Bose-Einstein Condensate could make an outstanding dielectric for a capacitor, assuming its breakdown potential and leakage properties are acceptable.
Driving with headlights on at 38mph (Score:1)
Cherenkov Radiation (Score:1)
I heard an interesting story once regarding Cherenkov radiation. Apparently in some of the older accellerators, in order to line up the detector with the beam of electrons (or whatever), the experimentalist would put his/her eye in the path of the beam and look at the Cherenkov radiation (typically blue) in order to see precisely where the beam was. The electrons were travelling (once in the eye) faster than the local speed of light, so they spit off Cherenkov radiation. But I'm not sure I'd really want them shooting on through my brain!
So.. (Score:1)
Night vision goggles? Sheya... (Score:1)
Actually, the BEC has a very tiny head capacity, so it probably wouldn't freeze your eyes... Of course, the vacuum chamber might break your neck...
didn't know ... (Score:1)
Atomic Blast vs. Elephant Farts (Score:1)
A bomb on the lab is still going to vaporize the whole shebang.
How did we get on this topic, again? I can't believe I'm talking about bombing a danish phyics lab.
Slow Glass (Score:1)
Help! Too hard! Speed of light != constant? (Score:1)
Punctuation is your friend (Score:1)
Light Sabers? (Score:1)
Ok, everyone has seen the light sabers in Star Wars. What if the handle contained a SUPER high powered laser and one of these devices. Then, when activated, the light would slowly extend until it reached a set limit. Then the device would get to 0 degs K and hold the light still.. Ok.. So I'm crazy.
Maybe I just like light sabers too much.
:-)
So.. (Score:1)
I don't think it's implied by this approach.
I've never really believed that the "maximum speed" of anything is the speed of light. It just seems odd placing a limit on something that we don't really know everything about.
Not really. I don't know everything about my car, but I have a pretty good idea what its limits are. We may not know everything about light, but we know some things. More importantly, we know quite a bit about the behavior of mass as it approaches lightspeed -- it acts in a way that very strongly supports the idea of a lightspeed limit.
It *may* be possible to somehow "sidestep" the lightspeed limit, but that's another question.
Memory? (Score:1)
There is a speed limit (not a bandwidth one) imposed on these networks because we can not pump data into them fast enough. But once data is in there, it's moving real fast.
It's moving so fast in fact, that a single bit of data takes up a whole lot of space. You need a very long piece of cable to 'pipeline' a very short burst of data. Hence, the lengths of cable in an optical FDDI ring must be pretty significant, else a data packet can start arriving at the original station before it's finished being sent. This poses a problem.
Now, with a EBC fiber, with light moving REAL SLOW, you can pump in individual photons for individual bits... So the data density per linear distance increases significantly, as the rate of transmission decreases proportionally. Not exactly a good solution for a networking medium...
But, consider a very short (distance) EBC optical buffer that data is stuffed into; and once full, a switch opens and a massive burt of data (oh, a GB) blasts down the pike at the speed of light.
It's not news (Score:1)
I've never openned it for fear of the sunshine getting out. But now, if I have some of this supercooled atom soup, I can open the can, capture the sunshine, and enjoy it during the New England winter.
So.. (Score:1)
light in vacuum. If information went faster you
would be messing up the sequence of cause and effect.
The light speed in non-vacuum hasn't got anything
to do with this though.
(and note that if it's not information it *can* go
faster than light, but it's useful for nothing anyway so..)
you *can* go faster than light in non-vacuum (Score:1)
light speed in non-vacuum (by that I mean faster than
38 miles/second in this case). It happens all the time in
physics experiments. It's a bit like going faster than the
speed of sound, it will be a light "boom" which is visible as a blue
corona. I'm not 100% sure but I believe the blue color
of the water in nuclear reactors are caused by this.
In any event I have seen many photos of the effect.
So.. (Score:1)
Now, just as the speed of light in space is a certain amount, so too is the speed of light in this substance the scientists are playing with. And just like you cannot exceed the speed of light while travelling through space, you can't exceed it if you were travelling through that super-cooled substance. Therefore, no object could accelerate even close to 38 miles per hour, inlcuding radio waves, fast cars, or Microsoft lawyers on their way to court with their latest faked video, while travelling through that substance.
Or something like that...
what happens when they slow light down to *zero*? (Score:1)
;-)
Slow Glass (Score:1)
VonSlatt
that's because... (Score:1)
...David
Light Capacitors? (Score:1)
Anti-gravity... (Score:1)
The idea being that the superconducting disk would diminish the force of gravity between any objects on opposite sides of the disk.
Probably BS, but whatever.
--
Use cypherpunks/cypherpunks (Score:1)
Petrus Vectorius
Slow Glass Practical Jokes + other issues (Score:1)
One thing I brought up was that the slow-glass farms would have to be really secure against tresspassing, else pranksters could moon the glass (only to be seen 10 years later), or worse.
Also: once installed, light from inside the house would start traveling throught the glass. 10 years later, someone could watch what was going on in your house. (Imagine the year is 2006 and we finally get to see OJ kill his wife?)
Light in a box?? (Score:1)
didn't know ... (Score:1)
Summary anyone ? (Score:1)
didn't know ... (Score:1)
No, no, no. (Score:1)
what?? (Score:1)
Absolute Zero (Score:1)
From what I remember when the temperature reaches Absolute Zero the atoms just stop moving?
Anyone have any info on it?
Neat Visual Effects (Score:1)
When a laser is shot through a glass of light it refracts and generally keeps moving as a ray. Cherenkov radition creates a nice blue glow. The question being, when light exits the Danish material, does it exit as a general glow or as a a slightly diffracted beam?
Cherenkov Radiation (Score:1)
Experimental physicists use this effect in things like neutrino detectors, such the AMANDA detector at the South Pole: fast-moving subatomic particles created by interactions between neutrinos and atoms inside the earth go zipping through South Polar ice faster than the speed of light *inside ice*, creating a flash of Cherenkov radiation. If you have light detectors embedded in the ice, you can pick up the flash; if you have enough detectors and good clocks, you can track the flash moving through the ice and figure out which direction the particle came from, which tells you where in the universe the parent neutrino came from...
I suspect the original poster's idea *won't* work because it relies on getting light to travel faster than the local light speed, which by definition may not be possible...but I'm not up on my relativistic shock wave theory.
why? (Score:1)
If you are going to do something like that, do something thats useful! (besides filling up space in the sunday paper!)
Big refractive index (Score:1)
So how do you measure the speed?