Nano-Scale Optical Co-Axial Cables Announced

toybuilder writes "Reuters reports that scientists have published their work on nano-scale optical coax in the most recent issue of Applied Physics Letters. The coax cable is only about 300nm wide, and is able to transmit optical signals using a carbon center conductor, transmitting light at about 90% the speed of light."

I have problems with regular coax...

[ArcherB]

The coax cable is only about 300nm wide,...

How do you plug it in?

Re:I have problems with regular coax...

[0racle]

Carefully

Very carefully

[symbolset]

With really tiny tweezers.

Re:I have problems with regular coax...

[kfg]

Doesn't matter, some kid with a Tonka backhoe is just going to end up dyking off the network anyway.

KFG

Re:

[Ferzerp]

coax?

do we really have problem with interference in fiber where we have to use coaxial cable???

Editors please!

btw: http://en.wikipedia.org/wiki/Coaxial_cable [wikipedia.org]

Re:I have problems with regular coax...

[halftrack]

do we really have problem with interference in fiber where we have to use coaxial cable???

Most (all?) fiber optical cables have a co-axial design. Simplified; there is a core and a cladding, with the cladding having a lower refractive index than the core; thus creating total reflection (multimode fibers.) Now the cladding could be the air surrounding the cable, but it's probably not, thus as you see the co-axial design is a reasonable one. (Though you could probably get a away with some off axis designs, at least for multimode fibers.)

Wikipedia on fiber optics [wikipedia.org]

As for the GP, he might be joking but that is actually a serious concern. To get the correct electromagnetic modes in the fiber you need to align your fiber with your source carefully. obviously this isn't easy when for instance connecting this 300 nm fiber to some chip ... probably mostly useful for integrated stuff. (NIDNRTFA)

Re:

[Ferzerp]

but that's not coaxial cable....

Mixed up with Seinfeld:

[norminator]

Kramer: Why, I've plugged in cables so small I couldn't even see them!
Elaine: How did you know you plugged them in?
Kramer: ... Well... I guess I just assumed...!

Re:

[pipingguy]

Monstercable?

Re:

[Random Destruction]

Er. you know, or your hand will slice through it like a giant piece of bipedal monkey through a tiny cable.

Re:

[Thuktun]

Er. you know, or your hand will slice through it like a giant piece of bipedal monkey through a tiny cable.

Depending on the tensile strength of the "cable", it might in fact slice through your hand instead of the other way around. 300nm is a VERY sharp edge.

huh?

[macadamia_harold]

The coax cable is only about 300nm wide, and is able to transmit optical signals using a carbon center conductor, transmitting light at about 90% the speed of light.

methinks the speed of light is whatever speed the light travels at.

Re:huh?

[mandelbr0t]

The physics constant c refers to the speed of light in a vacuum. Read here [rpi.edu] to find out why this statement isn't stupid.

mandelbr0t

Re:

[kfg]

the speed of light in a vacuum.

Appears to be zero. Now if you'll excuse me I have to go blow my nose and take a shower.

KFG

Re:huh?

[Incongruity]

Hardly -- the statement is a little stupid because it doesn't mention the constant c nor "the speed of light in a vacuum", it simply says "the speed of light" -- most people will recognize the error, but it's still an error.

Re:

[lachlan76]

The light will always travel at the speed of light, but it is absorbed and re-emitted by the medium, which takes a certain amount of time. This causes the average speed to be slower than the speed of light. So no, quoting the average speed as a percentage of the speed of light is not really an error.

Re:

[Instine]

Actually, in physics, there's no such thing as "speed". Only Velocity. Speed, strictly speeking, is meaningless.

Re:

[Incongruity]

Well, that's not the physics I was taught...velocity is a vector quantity and speed is a scalar quantity... essentially velocity without a direction. That doesn't make it any less real -- it makes it less informative, sure, but no less real. A rate of change is a rate of change, regardless -- the sign (i.e. +/-) or direction, as those can be arbitrary in some cases and in most others, it's only important that they're correct relative to other related rates.

Re:

[dwater]

So, not an error, just stupidly ambiguous.

Like saying something is as long as a piece of string. ...though, not quite, since the string's length has no upper limit, while, presumably, light can only be 'c' or lower. They both have a lower limit of '0' though, I guess...unless you get into theoretical physics, which, I suppose, this all is anyway...

Re:

[zippthorne]

It is both perfectly understandable and jarringly imprecise.

Re:

[solitas]

So, the material's 'n' would be around 1/0.9 = 1.1111 (n=c/v). I wonder what form of "carbon" it is - crystalline and amorphous diamond are in the range of 2.42-2.57...

Re:huh?

[Anonymous Coward]

Light always travels at 100% of the speed of light. However, in this cable, light travels at about 90% of the speed of light in a vacuum.

Re:

[stigin]

Well you are right in some sense... the individual photons always travel at the speed of light. The phase velocity however can be slower (and in fact also be faster) tha the speed of light. It is the later al these articles refer to since this is the classically measured propagation of a coherent bunch of photons aka a beam of light.

Re:

[A beautiful mind]

methinks it is like a weasel

Re:

[Gordonjcp]

What happens is that it gets gradually slower as each photon realises "Oh, I should be going 90% slower" with every Planck length that passes. Thus the speed of light through this fibre asymptotically tends to zero. It's actually pretty damn clever stuff. For a practical application, see "The Light of Other Days", by Arthur C. Clarke.

I fart into your general direction

[ArsenneLupin]

Furtssenvrietig

Yeah, right. And the glass spere does know nuthink about that guy. <big silent but smelly one>

Impressive Indices

[overshoot]

Wowsers. An index of refraction of only 1.1 is damned impressive.

The fibers are k3w1, but what I really want to know is how they got the silly things to be so much less of a "drag" than teflon. If they can extend that, it has a lot more immediate applications as a low- material than as a fast lightpipe.

Comments so far about 'speed of light'

[Meccanica]

As soon as I read that, it occurred to me that half of the comments were going to focus on that one sentence. And what do you know? I was right.

Nostradamus, are you not.

[ichigo 2.0]

You might want to cancel the pointy wizard hat you just ordered from theprophetshop.com, the summary is only two sentences long so half of the comments focusing on the second sentence isn't particularly odd. ;)

Thosands of times faster than electronics?

[JesseL]

From TFA:

"It's not quite the speed of light, but it's probably 90 percent the speed of light. That's still thousands of times faster than electronics," Naughton said in an interview.

It was my understanding that electric fields propagate through copper at about 1/3 C.

Re:

[Cutie Pi]

It's actually about 2/3 the speed of light (depending on the dielectric constant). The TFA might be referring to the drift velocity of electrons in the wire (on the order of a centimeter/s), which is not a particulary useful comparison.

Re:Thosands of times faster than electronics?

[KokorHekkus]

I thought it was a bit higher than that (still not 90% though). Did some digging and wikipedia came up with that the velocity of propagation was about .79 for a coax cable according to it. Checked a supplier of coax cables and they quoted velocity of propagation at .66 C to .84 C (latter for 1.13 mm copper KTV cable with PE insulation)

Source: http://en.wikipedia.org/wiki/Velocity_of_propagati on [wikipedia.org]

Re:

[leighklotz]

90%+ is possible for waveguides, and for open-wire feedline, but is usually lower for coaxial feedline.
VF is 1/sqrt(dielectric constant). Interestingly, the velocity itself is VF*c=1/sqrt(L*C) where c=speed of light in a vacuum, and L and C are the series inductance and shunt capacitance of the feedline, so those values are directly related to the velocity factor. Finally, given L and C we can calculate the characteristic impedance Z=sqrt(L/C).

The characteristic impedance of the coax is important to achie

thickness is the key issue

[rjdegraaf]

The 300nm wide fiber is the key issue.

The thinner the fiber, the less the digital light pulses are spread (due to reflections on the fiber shell) per unit distance, the more information can be sent through per unit time.

Thinner means more bandwidth.

Re:

[sexybomber]

I guess "fat pipes" is a misnomer, then.

Re:

[Schraegstrichpunkt]

How can anyone label this as informative?! It is utter bullshit. If it's a joke it might be labeled funny. The area of the fiber as almost nothing to do the amount of information it can transmit (disregard multimode singlemode etc.).

Well, it's vaguely correct in the sense that single-mode fibre (which is thinner) can be run faster than multi-mode fibre (which is thicker), but yeah, it's not exactly +N, Informative for N > 0

Re:

[Schraegstrichpunkt]

... So you did.

Re:

[rjdegraaf]

The area of the fiber as almost nothing to do the amount of information it can transmit.

Oh yes it does: the path of a light beam going through the center of the core is less than the trajectory of light which is multi-reflected against the core boundaries; therefor the initial digital light packet is spread out when passing a certain length of optical fiber. The spread-out is directly related to the radius of the fiber, hence the area.

Light inside a waveguide (and a fiber is one) does not spread in

The bottum line...

[Maliron]

I think the thing we need to think about is when this may be useful to us. Right now it has to cost around elevenity billion dollars to make just enough to test... I think I will stick with the current speed of light through fiber.

Yawn..

[djcatnip]

Wake me up when they announce nano-scale HDMI.

Coax is silly for optical

[smellsofbikes]

Will someone tell me *why* they did this? Yes, it's very cool. But the whole and only point of coax, as they talk about in TFA, is that it minimizes electrical influence.
If you're using light, there *isn't* any electrical interference, either as a transmitter or a receiver. That's one of the major benefits of using light.
So it's kind of pointless to make a coax, unless you really want a two-channel transmitter where one's a funny ring-shape. In which case, why not make optical ribbon cable?
Which brings up a wholly separate question: one reason industry has moved from parallel to very-high-speed serial is that you don't have to worry about timing and synchronicity, which are primarily due to impurities in copper. Is this an issue with optical? Coz the engineering is generally easier to run ten existing lines in parallel than to make one line ten times faster, if you don't have to worry about synchronizing them.

Re:

[fluffy99]

You obviously didn't read the entire article. The whole point is that they are shoving something with a wavelength of 375 nm down a 300 nm pipe. They explained that this is the exact same issue with shoving RF down a coax (ie 1-meter wavelengths down a 1/4" coax).

Re:

[smellsofbikes]

I must've missed that part, and I did read it. hm, weird.

Re:

[smellsofbikes]

kay, I've thought about it some more. So the wavelength's 375 nm: so what? Light's a longitudinal wave, not transverse. I'm not sure light *has* a diameter.

The issue with shoving RF down coax is one of minimizing impedance, not wavelength, which is why the same coax works well across a decade or so of RF. Antenna length *does* need to scale with wavelength, but unless you want your waveguide to act like an antenna, you probably don't want it to be tuned, or to need to be tuned, to the wavelength in ques

Re:

[HuskyDog]

OK, two important points about coax.

1. For any given size of coax there is a maximum permitted frequency. This occurs when the average circumference of the dielectric equals the wavelength in that dielectric material. This means that as the frequency goes up the diameter of the cable must go down. We see this clearly in the development of coax connectors for mmwave applications, where diameters are now around 1mm in some cases. If one operates above the maximum frequency, then the outer of the coax will

Re:

[smellsofbikes]

I'm going to have to think about that, but that's a great answer.

Re:

[StikyPad]

"Coax," short for coaxial, is defined as "having or mounted on a common axis." In cables, it is any design in which a central conductor is surrounded by a shielded cladding -- they both encircle a common "axis" or center. All fiber cables are coax, except those used in toys and art. Most have multiple levels of shielding to protect against energy loss/insertion, physical stresses and environmental hazards, in order from inner to outer.

Re:

[smellsofbikes]

Except that 99% of the time, coax means signal down the center, and signal return path (or guard, or whatever you want to call a conduction path) back through the cladding, which is the point of the shielding. That's why we use coax for RF, because it minimizes the loop area and coaligns the signal with the return, rather than just a signal path and a current return path running out to the antenna separately, each with a 20mm outdoor-exposure-rated rubber casing.

Re:

[StikyPad]

That's only because 99% of coax in common use is single conductor electrical shielded cable, which is to coax as sheep are to mammals. Electrical shielded cable is just a type of coax cable. Also the function of the shielding is to eliminate EMI, not to provide any sort of return path. That it is typically connected at both ends is incidental -- it's just the simplest method of grounding the insulation.

Re:

[smellsofbikes]

Here's an unbelievably cool demo of why return paths matter so very, very much. Unfortunately it takes some expensive equipment.
Take about 50-100' of coax. Strip the ends, and put a 50 ohm resistor between the center and the braid on one end. Attach the braid on one end to the braid on the other end with a 2" wire. Put DC on it and put a current probe around the 2" wire. 99.9% of the electricity flowing, is flowing through the 2" wire. Now put a 1 MHz square wave down the center conductor and measure

Re:

[Goldsmith]

They use coaxial wires so that their waveguide can be long and skinny.

It's thinner than the wavelength of the light, which is not possible with fiberoptics. There are other ways of making subwavelength waveguides, but they don't work over long distances. In the co-ax, light is transmitted basically as if it were in free space, and doesn't attenuate very much. In most nanostructures used for optics, light is transmitted as a plasmon (a rather quickly attenuating surface bound state).

There's a bonus third e

Re:

[smellsofbikes]

You're closer to convincing me than anyone else.
So tell me why the wavelength of light matters: it's longitudinal, not transverse, so what limits it? Does light have a diameter at all? I guess there's an amplitude, some function of the electronic/magnetic components. I know they're 90 degrees to one another. Are the two the same amplitude? Does it matter that it runs into things? I guess an electric field shouldn't be able to cross a conductor, but is that absolute, or is there some penetration into t

Re:

[pclminion]

So tell me why the wavelength of light matters: it's longitudinal, not transverse, so what limits it?

Uh, WHAT? Light is certainly transverse. The reason people get confused is when they look at a graph of an EM wave they see things WAVING up and down. Light doesn't do that. The waves drawn in diagrams only mean that the amplitude of the electric/magnetic field is increasing/decreasing as the wave travels along its path.

However, a light wave isn't (can't be) a perfect mathematical ray with changing ele

Re:

[Goldsmith]

There are a lot of solutions to Maxwell's equations beyond the version taught in introductory electromagnetism. In a co-ax, there are different states allowed than if there was just a metal tube. I don't really want to get more technical than that, because I'll get things wrong. You could think of this system as changing light from photons to electrons and back.

Why so slow?

[r_jensen11]

When we're working on quantum physics and teleportation, why are we focusing on something as slow as the speed of light? If we've already teleported information via cables in the sewers beneath the Danube [bbc.co.uk], why care about the speed of light, let alone anything less than it?

c the constant

[H0D_G]

Actually, the speed of light in a vacuum is not constant at all, according to several current theories. Professor R.T. Cahill's process physics theory(i mention this one, cause i've had some lectures on it, but there are others) states that the speed of light is actually inconstant, and depends on the flow of space around it. I don't claim to understand it, being a humble chemist, but it's interesting stuff http://www.arxiv.org/abs/gr-qc/0203015 [arxiv.org] for a cahill paper

Can't get the connector on

[mbstone]

Every time I try to solder a connector on a piece of 300nm-thick coax I wind up trying to strip off the shielding, but cutting off the inner conductor as well. Either that, or I forget to put the connector shell onto the cable first....

Re:

[ERJ]

The "absolute" speed of light is measured in a vacuum. As soon as light travels through any material it slows down to less then the absolute speed of light.

Re:

[PhysicsPhil]

The "absolute" speed of light is measured in a vacuum. As soon as light travels through any material it slows down to less then the absolute speed of light.

If you really want to be pedantic, the speed of light in a vacuum is not measured but rather defined to be 299,792,458 m/s.

Re:

[CrimsonAvenger]

If you really want to be pedantic, the speed of light in a vacuum is not measured but rather defined to be 299,792,458 m/s.

Of course, if you REALLY want to be pedantic, the speed of light in a vacuum is measured, and the meter is defined as being the distance light travels in 1/299792458th of a second.

Re:

[PhysicsPhil]

Of course, if you REALLY want to be pedantic, the speed of light in a vacuum is measured, and the meter is defined as being the distance light travels in 1/299792458th of a second.

While this is Slashdot, we still encourage pedantic comments to be correct. :)

Your definition of the metre is correct, but you may notice that it fixes the speed of light at precisely 299792458 m/s, with no room for measurement. What you actually do in modern science is measure a second with a very precise clock, and calibra

Re:

[itlurksbeneath]

Well, if you really, really want to be pedantic, the definition of a meter (or metre for the non-US majority of the world that actually USES the SI system) seems to be changing quite frequently (on a geologic scale, anyway). It used to be one ten millionth of the distance from the equator to the north pole (line drawn through Paris, France), then it was the length between two scratch marks on a platinum-iridium bar at 0C, now defined as the distance covered by the speed of light in 1/299792458 of a second,

Re:

[medge_42]

No, apparently not.
One university in the US (New Hampshire I think) had it down to 60km/h.

Re:

[medge_42]

I should mention that that was going through a block of sodium at -272C (near absolute zero)

Re:

[COMON$]

just curious, how do you cool something that well?

Re:

[imsabbel]

Liquid helium, under reduced pressure.
If you want to go even lower, than you can use adiabatic demagnetisation (put stuff into magnetic field->Spin orientation reduces entropy->remove heat->shut off magnetic field->the new degree of freedom reduces temperture).
Alternatively, you can try laser cooling (the closesed thing to a maxwell daemon we have), or diffusion cooling (with helium 3 and 4).

Re:

[tool462]

There's also evaporative cooling in a magnetic field. The atoms you are cooling are placed in a magnetic trap, and the more energetic ones "boil" off, leaving the remaining atoms cooler. This combined with the laser cooling is what was used to create the Bose-Einstein condensate that Eric A. Cornell, Wolfgang Ketterle and Carl E. Wieman won the Nobel Prize for back in 2001. link [nobelprize.org]

Re:

[COMON$]

Thanks, I know physics as a hobby nothing more. But I know little of low energy systems, I will have to look up a few of those terms though ;)

Re:

[medge_42]

You put in in an Aston Martin DB9.

Physicists in Helsinki have managed to get temperatures to 1 billionth of a degree above absolute zero.
I am more curious as to how you measure something that cold.

Re:

[Anonymous Coward]

That's nothing. I had it down to zero, using nothing but a block of wood.

Re:

[kitsunewarlock]

If time travel occurs beyond the speed of light, I've seen it at 88 miles per hour. And the earth once was spun backwards at that rotational velocity in Superman 1.
But seriously, when will we create a material that doesn't have light bounce off of it, but is reflected and bounces off of light?
Wait...Physists worked on this project. I thought they were too busy explaining Shrodinger to Peta.

Re:WTF?

[MustardMan]

Right, because the slashdot poster definitely understands the details of the physics publication in a peer-reviewed physics journal, written by experts in the field, and can clearly question its validity in the three seconds it takes to read a slashdot summary.

Here's an idea, instead of immediately trying to show how smart you are by posting minutes after an article goes up just to say "this is dumb", have a little faith in the scientific publication process and actually read the (original, peer-reviewed) article before you jump to conclusions.

Re:

[kfg]

. . .have a little faith in the scientific publication process . . .

Well, maybe he hasn't had half his brain sucked out yet?

KFG

Re:

[Anonymous Coward]

You have faith in the peer reviewed physics journal? You must not know any of the peers, or have any insight into the review process. Trust me, its a mess. Although I am not a physicist myself, my friends who are complain to no end at the state of affairs with the journals. Its not that everything published is wrong, its just most of it is very, very difficult to review and very very little of it is worth reading. Its never wrong to ask stupid questions, or compare new discoveries to existing models of thou

Re:WTF?

[MustardMan]

Yes, I DO have faith in the peer review process. It's far from perfect, but it's not as bad as you make it out to be. The thing you need to know is, a lot of physicists, and scientists in general (myself included) can be really anally retentive bastards. I one got blasted for fifteen minutes over my use of the phrase "high reynolds number" when the colleague in question believed "moderate" was the appropriate adjective and "high" was misleading. These are the types of errors that get physicists steaming, and with good reason - physics is perhaps the most rigorous of the sciences, and you have to be damn careful about how you word things. People will complain, loudly, about very minor issues. Many scientists strive for absolute perfection, and fixate on the negatives in an attempt to make the process better. There's nothing wrong with this, but it's useful to keep in mind when you form opinions about the peer review process based on your friends' complaints.

When people bitch about physics journals, in my experience it's been mainly for two common reasons:
1.) Drawing large, over-arching conclusions without enough evidence to support it. This is in no way saying the bulk of the work is invalid, just that the authors got a little greedy when writing the conclusions.
2.) Disagreement with the underlying assumptions that make up the paper. This one is trickier, but again it doesn't immediately invalidate the work, just questions how relevant the results are.

In either case, the peer review process, by people well-versed in the field, is a whole HELL of a lot more trustworthy than the slashdot peanut-gallery. The OP was full of crap, and others have gone into great detail to explain why he/she is full of crap. I was merely pointing out that the knee-jerk slashdot "post early, post often" karma whoring competitions lead to a whole lot of dumbass assertions without any firm understanding of the actual facts of the discussion.

Re:

[Bill, Shooter of Bul]

I was merely pointing out that the knee-jerk slashdot "post early, post often" karma whoring competitions lead to a whole lot of dumbass assertions without any firm understanding of the actual facts of the discussion.

But thats what slashdot is. Its a discussion forum. It wasn't a stupid question, as you can see it was asked in other places in this subject.Its about the exchange of ideas and is what makes slashdot a *good* place. Its like instant wikipedia that has people pooling their collective areas o

Re:

[MustardMan]

That's fine - an honest question is all well and good, and will no doubt be answered quickly. However, posting a reply with the subject "WTF" that takes on a "these people are idiots" tone in an attempt to get easy early mod points is a shining symbol of jackassitude. Acting like you are smarter than people who are experts in their field makes one look like a complete moron - that's not starting a discussion, it's flamebait and ego-stroking.

Re:

[Bill, Shooter of Bul]

Acting like you are smarter than people who are experts in their field makes one look like a complete moron - that's not starting a discussion, it's flamebait and ego-stroking.

but it did start a discussion. By that token everthing on the evening news is flamebait. The comment had attitude, but jeesh, do you really think he thought he was smarter than the person who wrote the article? Its subjective. You can't tell from a short comment like that what the author was thinking. I took it as a witty sacrasti

Re:

[Schraegstrichpunkt]

You have faith in the peer reviewed physics journal? You must not know any of the peers, or have any insight into the review process. Trust me, its a mess.

That may be the case, but unless you're a physicist, you're still better off trusting the journals than your own pathetic knowledge. It's much like reading an article about computer security in Wired. Is it likely to be inaccurate/simplistic/stupid? Yes. Is it still better advice than what most non-techies can come up with on their own? Yes.

The journals are still far more credible than, say, Answers in Genesis, or Time Cube.

Re:WTF?

[kebes]

Well put. The original scientific article in question is this one:

Rybczynski, J.; Kempa, K.; Herczynski, A.; Wang, Y.; Naughton, M. J.; Ren, Z. F.; Huang, Z. P.; Cai, D.; Giersig, M. "Subwavelength waveguide for visible light" Applied Physics Letters 2007, 90, (2), 021104. (doi: 10.1063/1.2430400).

The paper is here [aip.org], although only subscribers can read the fulltext. The abstract says this:

The authors demonstrate transmission of visible light through metallic coaxial nanostructures many wavelengths in length, with coaxial electrode spacing much less than a wavelength. Since the light frequency is well below the plasma resonance in the metal of the electrodes, the propagating mode reduces to the well-known transverse electromagnetic mode of a coaxial waveguide. They have thus achieved a faithful analog of the conventional coaxial cable for visible light. ©2007 American Institute of Physics

These are extremely small structures and this leads to an interaction between the light (which is an electromagnetic wave of course) that is essentially identical to when radiofrequency EM radiation propagates down a normal (macroscopic) coax cable. Specifically, in the introduction they say:

In this work, we show experimentally that a nanoscopic analog of the conventional coaxial cable, with properly chosen metals for the electrodes and proper electrode dimensions, indeed retains approximately all of the above properties of its conventional macroscale cousin.

Then they go through the details. Their device uses a multiwall carbon-nanotube (MWCNT) as the center conductor (it is a 'metallic' CNT). The MWCNT is embedded in aluminum oxide, which acts as the optically transparent 'dielectric'. The outer wrapping electrode is made of chromium.

The mere creation of these nano-sized devices is quite an accomplishment. The fact that they've demonstrated successful transmission of light through these sub-wavelength sized devices is even more impressive. I can imagine a wide range of applications in nano-scale imaging (imagine a massive array of NSOMs [wikipedia.org]), lithography, or even optical computing.

Re:

[Steve525]

While I'll agree with your assesment that this is really cool work, (the first demonstration of a coaxial cable at optical frequencies), I'm not sure if any of the applications you list are likely.

NSOM: You really want something that's much smaller than the wavelength. This isn't.
Lithography: Optically lithography works well because you project trillions of pixels at once. Something like this could only approach maybe a million or so. And like NSOM, you want something smaller than this will ever be.
Opti

Re:

[A beautiful mind]

You must be new here, right?

First of all, if you thought the OP was the only thing he will post, then you're wrong.

5 people will point out where exactly is the original paper mistaken, then
4 people will write a post about how dare those 5 people challenge a peer reviewed journal,
the original 5 plus 15 new people will point out the flaws in that argument,
10 people will post "in soviet russia you suck vacuum" jokes, of which the first 6 will be modded redundant and the last 4 modded up to anything betw

Re:

[monopole]

Actually some of us slashdot readers have Ph.D.s in physics and have literally "done the math". But I frankly did say WTF? at first. While this won't replace optical fibers, it does have very interesting implications for phase shifting and the like.

Re:

[j00r0m4nc3r]

From TFA:

"This enables the cable to carry electromagnetic signals with wavelengths bigger than its own diameter."

Re:

[Schraegstrichpunkt]

Interesting. I wonder if we could make some nifty antennas out of that.

Re:

[silentounce]

co = two
axial = "being or situated in line with an axis" or "around or about an axis (a link between two or more places)" or "along, or parallel to, the main axis; lengthwise, longitudinal"

The term coax has nothing to do "spefically" with conveying electric current. That just happens to be its most common use. Etymology is your friend.

Re:

[silentounce]

And before anyone says anything... I should have said, co = Together; joint; jointly; mutually.

Re:

[ArcherB]

Coax for light?

Why?

Think processors that produce less heat, but don't look at them directly without eye protection. As speeds ramp up, heat sincs will be replaced with tinted shields.

Re:

[wass]

In the simplest sense, light here refers to light 'waves', which are the propogating electric/magnetic fields which are solutions to Maxwell's equations given the proper boundary conditions of the coaxial cable.

Of course this particular case involves a tiny coax, so if the wavelength of light is of order or larger than the size of the coax (I'm too lazy to read the article to see what wavelengths are used), then one would probably need to consider quantum mechanics and QED, to get the full behavior of the d

I just skimmed the article

[wass]

They transmitted visible light through the coax, which basically means it's like a typical coaxial cable transmission line [wikipedia.org] we're used to, but due to the small geometry they can still send TEM waves up to the frequencies of visible light.

In other words, this nano-coax-cable has the proper physical characteristcs such that optical frequencies of EM radiation (ie, visible light) can be transmitted without significant dissipation [wikipedia.org]or dispersion [wikipedia.org].

Re:

[EnderGT]

Congratulations, you only missed being first to point this out by 30 minutes! You missed second or 3rd 28 minutes, 4th by 10 minutes, and 5th by 5 minutes.

Sorry about your impending Redundant moderation.

Re:

[funwithBSD]

Sorry, fresh out of mod points...

Re:

[syousef]

I view at +4 and didn't have time to check. You have all the time in the world though I see. Too much time.

Re:

[MustardMan]

No, it doesn't sound like the author didn't graduate high school at all. The constant c is almost universally referred to as "the speed of light". Only rarely is the "in a vacuum" tacked onto the end. It's perfectly understood that when you refer to "the speed of light" that it means "the speed of light in a vacuum". Your nit-picking is pointless and goes against the convention used in thousands of published books, papers, articles, ad nauseum.

Re:

[syousef]

Yes and speed and velocity are used interchangeably, but if you're talking physics and do that you're a twit.

The nit picking as you put it isn't pointless. The point is that if you're talking science and don't get the jargon right you become much more ambiguous and it's a bad habit to form. Yes in this case it was obvious what he meant but that doesn't make it a good story submission.

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[MustardMan]

The point you're missing is... HE DID GET THE JARGON RIGHT. I've taken plenty of physics courses, in fact all the physics courses one needs to get a PhD in physics, and I heard the qualifier "in a vaccuum" mentioned a handful of times at best. The jargon is "speed of light", no "in a vacuum needed". You'd have to be a complete twit to demand the presense of this extraneous modifier when the meaning is already understood. Saying what you mean in a clear, consise, and compact manner is much more important

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[syousef]

I've also studied physics (Astronomy at Masters level). I've also published so that doesn't impress me or make you more qualified to comment than me. You demonstrate exactly the sort of elitist pig headed attitude that makes most science papers so damned unreadable. The context wasn't clear in this case at all. The only thing that made it clear was background knowledge on the subject. If you're expecting everyone who reads /. and has an interest to have taken physics classes, you're smoking wacky weed. Get

Re:

[Cyrom]

When not qualified the term "speed of light", to the majority of the population (except maybe a few who think they are clever for pointing out the lack of said qualification), means the speed of light in a vacuum. When one is referring to the speed of light through some other medium it is usually stated as such.

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[Bloater]

That is not correct. Read up on QED, the most accurate description of the interaction of light and electrons ever devised (Quantum Electro-Dynamics).

Light travels at a variety of speeds in the face of interactions or when travelling through free space. What is constant is the number of times the little arrow spins in a given vector length through spacetime (watch the Feynman lectures to get this "little arrow" reference at http://www.vega.org.uk/video/subseries/8 [vega.org.uk])

Didn't seem problematic to me

[Dachannien]

I mean, each pound of dark matter weighs over ten thousand pounds, so light moving at 90% of the speed of light seems pretty reasonable to me.