Rice Contracted to Provide NASA's Quantum Wire

geekman writes "NASA is paying Rice University $11 million to build a prototype quantum wire that can conduct electricity 10 times better than traditional copper cables at one-sixth the weight. Rice has four years to build a one-meter-long quantum wire, which will be made out of carbon nanotubes. Seems like a lot of money for a little wire, but then again, all the rocket scientists at Los Alamos have only ever been able to put together a four-centimeter nanotube."

The unfortunate thing about quantum wires...

[Anonymous Coward]

Is that they never seem to be where you left them. Although on a good day you'll end up with more than you started with depending on what universe you're in.

Re:The unfortunate thing about quantum wires...

[smokeslikeapoet]

One thing's for sure, you know exactly where it is not.

Re:The real question is..

[Masami Eiri]

They strangle the cat... maybe. Or maybe the cat knits them into a gas mask to protect him against the gas. Or maybe the gas reacts with them and creates a quantumn explosion...
Damn you Schrodinger!

Re:The real question is..

[B3ryllium]

... and the cat gets stuck bouncing through time in other people's bodies, until it finally lands a dreary part in a sad series based on a humdrum spinoff premise?

With a horrible theme song that sounds like someone strangling Scott Bakula?

It's Backwards Universe! Where all cats are Scott Backula, and all Jonathan Archers are Cats!

All your base are belong to us.

Seems like a lot of money for a little wire,

[scottv67]

Seems like a lot of money for a little wire,

Yeah, but it's still cheaper than Monster Cable.

;^)

Re:Seems like a lot of money for a little wire,

[ErikTheRed]

An erudite piece on Monster Cable, their products, business strategies, ethics, &c.:

Linkage [somethingawful.com].

A quote from within said piece to entice your fancy:

Of course these wires cost nearly as much as the DVD player itself, even more if you include the Monster-brand power filtration adapting converter unit which instantly converts your cash into lines of high grade Columbian cocaine for the company's CEO.

How much for a space elevator cable?

[EmbeddedJanitor]

Lemme see $11M/m x 15000km x 50 strands... Vokkov Bill Gates go stand in the poor people's line.

Re:How much for a space elevator cable?

[serutan]

The space elevator people at LiftPort expect carbon nanotubes of unlimited length to be available and cost-effective in 13 years. Whether they're right or not is anybody's guess, but the progress from a few nanometers to a few centimeters is 4 orders of magnitude in 4 years -- leaves Moore's law in the dust. Just 3 more orders of magnitude and they'll be in the tens of meters, and at that point I bet they'll be able to make them pretty much any length they want.

Moores law

[EmbeddedJanitor]

Nanotech not the same thing

I think you've made a very good point here. Moores Law is not about increase in size, it is really about decreasing the size of the transistors. The first transistors were huge things and it's all about preserving the physics while making things smaller.

This is a fundamentally different thing to using Moores Law as a prediction on scaling up something that only happens on a very small scale (eg. nano tubes or fusion or whatever).

How long...

[Evanisincontrol]

How long until some eccentric billionaire pays Rice to wire his entire house with that stuff?

"My house is iced out with quantam wiring, biatch. Or something. Bling bling."

Re:How long...

[nebaz]

So if you use twisted pair quantum wiring for broadband, and setup vpn, would that be quantum tunneling? (Sorry) :-)

Re:How long...

[Dr. GeneMachine]

Wouldn't that give problems with latency and response times? I mean, let's say, you do a ping. It gives you the round-trip time. Now you know how fast your packet is - which means you do not know any longer where it is. Would that be a dropped packet? How are you supposed to ping on your quantum tunneling thingmabob anyway??
Ah, newfangled codswallop! When we were young, we pushed carts full of punched cards from the terminal to the mainframe and back! Uphill both ways!! And we liked it!!!

Re:How long...

[ikkonoishi]

Not really.

You couldn't get sufficent precision with ping for uncertainty to come into play.

Re:How long...

[NanoGator]

"So if you use twisted pair quantum wiring for broadband, and setup vpn..."

That's a bit of a leap.

Re:How long...

[ErikTheRed]

That's a bit of a leap.

A... quantum... leap? (yup that joke's as bad as I thought).

Re:How long...

[NanoGator]

" (yup that joke's as bad as I thought)."

Grrr that's because you changed the punchline by observing it!

Re:How long...

[SamBeckett]

Leave me out of this.

Re:How long...

[fr2asbury]

Shh! Don't give the audiophiles any idea.

More poorly spent money...

[physicsphairy]

NASA is paying Rice University $11 million
Rice has four years to build a one-meter-long quantum wire,

Wouldn't it make a lot more sense to put out a bounty on this wire? Instead of the four year plan, you get the "everyone scrambling to complete it first" plan, and as a bonus, even when someone collects the bounty, all the research done by other institutions still stands.

Re:More poorly spent money...

[grumpygrodyguy]

Wouldn't it make a lot more sense to put out a bounty on this wire?

Not really, too much risk. It's an unevaluated process. Besides, how many companies would enter? Ten, 150? You've got better chances winning the world poker tour. Bottom line, everyone who isn't first place gets burned and left with a huge bill, no patents, and no $11Million.

Re:More poorly spent money...

[nacturation]

Bottom line, everyone who isn't first place gets burned and left with a huge bill, no patents, and no $11Million.

No patents? That assumes this quantum wire can be constructed in one step. If it's more than one step, you can patent everything along the way even if you never get the final step complete -- such as making it feasible at room temperature or something. And, in failing, you might find something that works for other applications. Read up on the history of the Post-It for one such example.

Re:More poorly spent money...

[XMyth]

Damn inventors. How dare they ask to be paid for their ideas. Scum I tell ya, scum.

Re:More poorly spent money...

[cnkeller]

Bottom line, everyone who isn't first place gets burned and left with a huge bill, no patents, and no $11Million.

You mean like the X-prize? We saw how badly that one worked out for people? Seriously, competition is a good thing.

Re:More poorly spent money...

[aptenergy]

Sure, but most universities won't have the experience to do it. Smalley won the Nobel Prize for his work with buckyballs (carbon-60, buckminsterfullerene, fullerene); carbon nanotubes are rods with essentially the same structure as buckyballs (the capped ends are two halves of a fullerene, iirc). Rice is obviously a leading pioneer in the field, nanotubes are Rice's specialty, and there's no reason to have a bounty when you have a Nobel Prize winner working on it.

Re:More poorly spent money...

[mattmatt]

(the capped ends are two halves of a fullerene, iirc)

Halferenes?

Re:More poorly spent money...

[IWannaBeAnAC]

And where would the universities get the upfront funding to hire students and researchers to do the work?

Re:More poorly spent money...

[Anonymous Coward]

I've heard that Rice is one of the most productive sources of research into nanotechnology. They've gotten this grant because they are qualified for it. This isn't something that you can do without funding so if there were a bounty all of the competitors would still need large grants in order to do the research.

Also the bounty would result in even more infighting than is usually seen in the scientific community.

Re:More poorly spent money...

[geekoid]

good point, but nows the RnD is being done with public money. this means the data will be public, and then anyone can take the info and start there own company.
If it was a bounty, companies would retain the rights to not only the carbon tube, but the process and discoveries which could have other applications.

Re:More poorly spent money...

[billbaggins]

Isn't that the sort of thing that the patent system was originally intended to promote? Where the "bounty" is the short-term monopoly on your invention...

Re:More poorly spent money...

[iammaxus]

Very simple: Universities won't put down the $10 million or so that it takes to complete this project without knowing for sure that they will be paid back.

Re:More poorly spent money...

[fermion]

This is called "basic research." It probably won't work, and if it does, will be far beyond even a VC event horizon.

Any money for this would come from the government through the grant writing process. The number of labs who have a C-60 reactor, and have good control over it, are still reletively small. Not to mention the ability to characterize and sort.

This is not like, say, the space plane, in which most technology is 5-10 years old and all that was required was a bit of money for engineering. These are molecules that really do not yet exist in huge quanities, and putting them together is not well understood. Hell, even the theory of how they conduct electricity is younger that superconductors, and just see how many of those we have around.

Rice and NASA have a very good working relationship. Rice has some of the best people to deal this type of Nanotechnology, plus enough other funding to leverage this small amount of money into a working product.

Re:More poorly spent money...

[pauldy]

Relativly small amount of money? Whats in your wallet?

When I think nanotech Rice isn't exactly the first place that comes to mind.

Minor nitpick on superconductivity....

[Impeesa]

Hell, even the theory of how they conduct electricity is younger that superconductors, and just see how many of those we have around.

As an aside, superconductivity is now very well understood. It's just that the race for a room-temperature superconductor has stalled out. In those fields where they can afford to keep the superconductors below critical temperature (e.g. NMR/MRI machines), superconductors are very widely used.

Fun fact: If you accidentally press Enter while typing in the subject line, your message is submitted as-is.

Nitpick on your nitpick

[MojoRilla]

As an aside, superconductivity is now very well understood.

Not according to the April 2005 issue of Scientific American. In an article entitled Low-Temperature Superconductivity Is Warming Up [sciam.com], it says that magnesium diboride defies traditional theories about superconductivity. From reading the article, it seems that superconductivity isn't really well understood at all.

Re:More poorly spent money...

[Lonewolf666]

Good point. I'd like to add once cheap mass production seems in range, venture capital will show up:
Cables like this might far outperform copper as winding in electric motors or loudspeakers. That is a big, existing market where better cable could make an immediate difference.

Why is NASA funding this?

[Scott7477]

I think that this type of research would be better funded through the Department of Energy or the National Science Foundation or DARPA. Certainly quantum wire would be useful in construction of spacecraft, but I think NASA should be focused more on space exploration. In other words, building spacecraft with existing technologies or tech that is likely to be feasible in the near term.

Re:More poorly spent money...

[Goldsmith]

Yeah, it would make more sense, but that's not the way research is done.

That money isn't a reward or a bounty, like the X prize, it's money that's going to be used right now to fund the research. There's very few other places that they're going to get the money to fund themselves, no venture capital or investments.

The goal in science is not to make money, it's to do great research. Other people are scrambling to do it first, and they've been given they're own funding.

Re:More poorly spent money...

[Java Ape]

PhysicsPhairy: Surely with a name like that you're familiar with the way academia works. Paying a bounty for a development worked well for things like the X-prize, but it basically attracts high-rollers with a dream looking for some recognition. The prize wasn't as large as the total expenditure of the winning team, and the losing teams are simply out of luck, financially speaking.

Primary research is both time consuming and expensive. When looking at a long-term, money intensive projects, requiring a t

Will no one think of the birdies

[Timesprout]

how are they supposed to land on quantum power lines!!

Re:Will no one think of the birdies

[TheSHAD0W]

Better hope they never succeed, you'd probably wind up with bird crap landing inside all the buildings in the area...

Thank god for Condi

[Anonymous Coward]

Condi Rice can build anything, she is one of the jewels in Bush's hat.

Don't tell me you didn't misread the title at first either!

wait a second...

[double-oh three]

Are nanotubes really quantum? They're very small, but I don't think they're actually at the quantum level of physics.

Ballistic Conduction

[DumbSwede]

I believe this refers to the ballistic conduction that takes place in carbon nano-tubes and is a quantum phenomenon. Basically electrons experience a small resistance entering and leaving a nano-tube, but then near zero resistance travelling along them.

Re:Ballistic Conduction

[mikael]

There was a theory that carbon nanotubes would support Cooper pairs (if impurities were added).
Described in this paper [arxiv.org].

Re:Ballistic Conduction

[IWannaBeAnAC]

No, quantum wires have a resistance that increases logarithmically with the length, rather than linearly for normal (ohmic) wires.

Exactly zero resistance would be an ideal conductor. I don't think there are any examples of ideal conductors that are not also superconductors, which implies low temperature.

Re:Ballistic Conduction

[HermanAB]

How the heck is that possible? If you would take a 1m wire and cut it into short pieces and solder them together with a different conductor, then the overall resistivity will be less than when you had a single piece of wire???

Re:Ballistic Conduction

[RedWizzard]

If you would take a 1m wire and cut it into short pieces and solder them together with a different conductor, then the overall resistivity will be less than when you had a single piece of wire???

No, other way round. A 2m piece of this wire would have less than double the resistance of a 1m piece. To clarify your example: say the 1m piece of wire has resistance R. Then you cut it into ten smaller pieces. Each of these pieces will have resistance greater than R/10. Stick them back together with some othe

Re:Ballistic Conduction

[HermanAB]

OK, so to get a good cable, your nanofilaments must be as long as possible - it won't help twisting a bunch of short ones together.

Still, there must be a limit as to the amount of current a tube can carry. What happens when this limit is reached?

Re:Ballistic Conduction

[RedWizzard]

Yeah, long wires. That's why NASA are aiming for 1m. Higher current can be handled by bundles of long wires.

Re:Ballistic Conduction

[IWannaBeAnAC]

The other way around. If you took a 1D wire, cut it in half, and spliced the ends together with a non-quantum join of negligable resistance (eg with a small piece of an ordinary conductor), the overall resistance (and resistivity) would be greater than the original.

Re:Ballistic Conduction

[QMO]

"resistance is independent of its length"

Logically this implies that once inside the nanotube there is no resistance to travel along it.

Let X be the resistance of a nanotube of length Y.
Since resistance is independent of length, changing the length of the nanotube does not affect the resistance.
Thus, X is also the resistance of a nanotube exactly the same as the first, except with length 2Y.
Therefore, the additional Y length of nanotube has no resistance.

I know nothing about nanotubes, and I also know th

Re:Ballistic Conduction

[Tim C]

Yes; the statement "resistence is independent of length" suggests to me that there is a resistance at either (or both) end(s) - ie a resistance to getting the electrons in and/or out of the wire. Once they're in, however, there's no resistance.

Note that I have no idea what I'm talking about; we didn't cover nanotubes in my degree :-)

Re:Ballistic Conduction

[Chris Burke]

Now I'll admit I'm not at all knowledgeable in this area, but I do have a hard time believing that a real-world object could have O(1) resistance. Any possibility for slowing down the electrons is going to scale with the length. Is this a theoretical property of carbon nanotubes, or does it apply to carbon nanotubes manufactured in the real world?

Re:Ballistic Conduction

[IWannaBeAnAC]

1-dimensional quantum systems have special properties. The charge carriers in 1D wires are not holes or electrons but instead are collective modes that have quasi-long-range order and carry the spin and charge of the original electrons as separate modes. This is kinda bizarre and has no analogy that I know of outside of quantum mechanics, but it gives 1D conductors rather unual properties.

One of these properties is that the resistance scales logarithmically with the length (not constant, the GP is incorrect). It is still remarkable though, because all other conductors have a resistance that scales linearly with the length (which seems intuitively obvious - but is wrong!).

Re:wait a second...

[Goldsmith]

Yes, they are.

A metallic carbon nanotube carries 4 quanta of current (4 charge carriers at a time): 2 conducting channels, 2 spins per channel. That's what NASA is referring to as a quantum wire.

Most of the resistance in such a wire is due to the fact that only a very few number of charge carriers can be transmitted at any time. The electrons going through the wire do not lose any energy in the wire, as there are no available lower energy states for them scatter into, and only two possible directions of motion (foward and backward). Thus, a perfect nanotube can be thought of as a "ballistic" conductor. There is some resistance to putting current into it and getting it back out, but in between, there is no resistance in the normal sense. (Although this sounds a little like superconductivity, it is definitely not.)

In a real nanotube, there are defects, contact resistances, impurities and environmental factors which act as transmission barriers, raising the probablility that an injected electron will reflect back to the source and not make it all the way through. It will be interesting to see how the Rice guys plan on annealing or growing their meter long wire to maintain the desired properties (and that's where the money comes in). Simply weaving a bunch of small nanotubes together is not going to cut it.

Re:wait a second...

[John Hasler]

A metallic carbon nanotube carries 4 quanta of current (4 charge carriers at a time): 2 conducting channels, 2 spins per channel. That's what NASA is referring to as a quantum wire. Most of the resistance in such a wire is due to the fact that only a very few number of charge carriers can be transmitted at any time. The electrons going through the wire do not lose any energy in the wire, as there are no available lower energy states for them scatter into, and only two possible directions of motion (foward

Yay magnets

[nounderscores]

If you can get a charge running forever around a ring of quantum wire, could this mean room temperature 10T magnets?

No more liquid helium!

Or is there something I'm missing here?

Re:Yay magnets

[Goldsmith]

In a real superconductor, any magnetic fields are expelled from the metal, that doesn't happen in a nanotube (at least as far as I know).

So for a superconductor "turned on" in a magnetic field, a balance is reached between the current and the magnetic field. The current and the resulting countering magnetic field are retained even when the original field is turned off. That effect is what keeps the current flowing forever, if it were to stop, the magnetic field excluded by the metal would change and viol

Re:wait a second...

[dabigpaybackski]

Simply weaving a bunch of small nanotubes together is not going to cut it.

Yes, but think of the scarf you could knit... Maybe throw in a matching fullerene watch cap.

uh oh

[fred fleenblat]

carbon nanotubes...that's awfully similar to the Inanimate Carbon Rod.

Get it right

[Tiger4]

" all the rocket scientists at Los Alamos have only ever been able to put together a four-centimeter nanotube."

They're nuclear scientists, not rocket scientists, dammit. Give'em a break!

Re:Get it right

[dabigpaybackski]

Levity aside, just remember how much trouble Corning (or whoever it was) had extruding their first fiber optics. The quality was crap, the production cost obscene. Everybody thought the technology was pie-in-the-sky unattainable. Then they got their manufacturing technique down and now we're awash in the stuff.

Wait a couple of decades and this carbon nanotube shit will be everywhere, notwithstanding the crudity of these initial experiments. Superconducting electric motors/turbines would be nice, for s

Reference and extra-info

[Spy der Mann]

For those who didn't read the past article on quantum wires [slashdot.org], here it is.

And for those who don't know what an armchair nanotube is, here are some images [mtu.edu] (The armchair nanotube is the one in the middle).

It will be interesting to see

[Future Man 3000]

Which approach they will take towards crafting this wire. It's almost a given they'll use carbon nanotubes because of the ballistic conduction property that will permit arbitrary-lengthed wires to pass electricity without resistance, but will they go with a singlewalled CNT or will they sacrifice perfect conductivity for stability and go with a multiwalled CNT?

These things could be the next revolution after fiber optics for network communication, so there is reason to be excited. I wonder if there would be too much interference to run these things in a twisted pair configuration.

Re:It will be interesting to see

[shadow303]

Your post reads very much like some techno-babble from Star Trek. I can't tell for sure whether you actually have an intelligent post, or whether you are just doing an exceptional job of faking out the moderators. Either way, bravo ;-)

Go Owls

[Anonymous Coward]

I'm sitting about three blocks from the Rice Campus & I'm a Rice grad, so pardon me for cheering 'em on.

This actually makes (some) sense - Dick Smalley & Robert Curl on the Rice faculty (and a 3rd guy in England) won that trivial little prize - the Nobel in Chemistry for basically inventing/discovering the buckyball and related carbon nano stuff - or something like that. I also seem to recall that Smalley also has done pretty well in acually being able to manufacture buckyballs.

Also, there is a long history of collaberation between NASA and Rice. Starting before the Apollo program. I had a professor at Rice who designed experiment packages that went to the moon in the Apollo program.

So, if NASA was going to award a contract or grant to somebody for this, Rice does make some sense.

Also, kind of interesting that President Kennedy gave the famous speech "We choose to go to the moon in this decade and do the other things, not because they are easy, but because they are hard..." on the Rice campus.

Re:Go Owls

[Don Negro]

"Why does Rice play Texas?" ;)

It's a proof of concept

[andrewzx1]

If Nobel lareat Smalley and his lab can build a proof of concept of the Carbon nanotube superwire, it would be worth far more than a few million $. This kind of technology would seriously revolutionize Western society. With a super wire you can build electic motors that are both many times stronger at the same power, and are much more efficient. The resulting stepping motors would revolutionize robotics. The wires would change how we deliver power, and even possibly, basic electrical circuitry. Imagine high current density superconductor wires at room temperature.

Carbon nanotubules, when properly, manufactured could also have very high tensile strength. Many times stronger than stranded steel cable and weighing less as well. This is the technology people what it use to build the space elevator.

Of course, after proof of concept there are still many challenges to cost effective manufacturing.

There are a dozen revolutionary uses for super wires. But first we need a proof of concept. FYI - I'm looking for a job at a well-funded nanotech startup. Many qualificiations, inquire within!

Re:It's a proof of concept

[iammaxus]

Could you please explain what you mean by increasing strength (torque?) at a given power? Do you mean for a given size of motor, you can have higher torques and lower rpms? I know that electric motor efficiencies are as high as 95% so the only way to get "many times" higher torques for a given power is to lower angular velocity. Additionally, how will they make electric motors much more efficient (again given electric motors are already commonly 80-90%+)? I assume you are talking about squeezing out an

Re:It's a proof of concept

[aXis100]

The main limitations on electic motors is heat - the wires will melt once you start pushing too much power.

With more conductive wires, you can get higher currents and thus higher power for the same size motor. Losses will be about the same becasue you'll just scale your motors to a suitable heat level again.

Higher power/weight ratios will make everything else that uses them lighter and more efficient.

Re:It's a proof of concept

[ramblin billy]

The dudes at Rice invented 3 of the 4 current methods for producing buckytubes. Their current research involves the use of catalysts applied to the end of existing tubes which results in "cloning" the tube, allowing for unprecedented control of the tubes characteristics. Here [house.gov] are some of Smalley's comments on buckytubes...

"These single walled carbon nanotubes are uniquely specified by two small integers, n and m. The diameter is roughly proportional to the sum, n+m. The electronic properties, however, are determined by the difference, n-m. If n and m are the same, then n-m=0 and the tube conducts electrons like a perfect metal. In the trade it is called and "arm-chair" tube. Electrons move down this tube as a coherent quantum particle, traveling down the tube much like a photon of light travels down a single mode optic fiber. Individual armchair tubes can conduct as much as 20 microamps of current. This doesn't sound like much until you realize that his little molecular wire is only 1 nanometer in diameter. A half inch thick cable made of these tubes aligned parallel to each other along the cable, would have over 100 trillion conductors packed side-by-side like pipes in a hardware store. If each of these tubes carried only one microamp, only 2 percent of its capacity, the half inch thick cable would be carrying one hundred millions amps of current. Fabricating such a cable - we call it the "armchair quantum wire" - is a prime objective of our work."

Buckytubes exceed the strength of carbon fiber (30 to 100 times that of steel), the thermal transfer ability of diamonds, and are the best electrical conductor of any molecule known. They promise great advances not only for the transmission of energy, but also for energy storage (including hydrogen), composite fabrics, and even solar power. The world's leading producer of buckytubes is Carbon Nanotechnologies Incorporated [cnanotech.com], a Houston based spin-off from Rice. In the computer category, IBM [ibm.com] has already announced the successful manufacture of buckytube transistors. It may not be all that long until we start to see some real world applications that begin to fulfill the exalted "gee whiz" promise of nanotechnology. And I'm not talking about facial creams.

billy - no...they are NOT calling the transistor 'little blue'

Re:It's a proof of concept

[Linker3000]

At last we'll be able to make some cables to take the current to charge those 'instant charge' batteries mentioned a while back!?

A problem of scale...

[TripMaster Monkey]

Let's just hope the kids at Rice don't get confused and wind up making a ridiculously large model [slashdot.org] of a quantum wire instead. :P

Sheesh, shoulda looked in Audiophile

[SteeldrivingJon]

I'm sure there's some outfit in Audiophile magazine that will sell you "quantum wire".

I hear it gives you really crisp trebles.

Why not ask Zyvex to make it?

[daVinci1980]

I'm a bit surprised that NASA didn't ask Zyvex [zyvex.com] to work on this for them... I have friends who work there, and they do some really neat stuff. (Including working on those crazy quantum nano-tubes).

Contrary to popular belief, their office is actually quite large.

Further strains on my loyalty to my alma mater?

[shanen]

My basic reaction is that superconducting approaches make much more sense. Weight is pretty much not a factor for normal usages. When the quantity of electricity involved is large enough that the weight does become a factor, then you're probably thinking of power transmission lines, and in that scenario you can consider the tradeoff for seriously large amounts of power. I can imagine a small refrigerated tunnel containing a high-temperature ceramic semiconductor and carrying extremely large amounts of elect

Re:Further strains on my loyalty to my alma mater?

[Frumious Wombat]

Weight may not be a factor, but flexibility is. Traditional superconductors are ceramics, where breaks between domains ruins the transmission. Carbon nanotubes, OTOH, would be flexible, and could be routed in manners than relatively rigids ceramics couldn't. The would also be more resistant to failures due to flexing.

It would be interesting to know the weight of the wire in current launch vehicles, as every kilo less of copper wire is a kilo more of payload you can lob into orbit.

Re:Further strains on my loyalty to my alma mater?

[ErikTheRed]

My basic reaction is that superconducting approaches make much more sense. Weight is pretty much not a factor for normal usages. When the quantity of electricity involved is large enough that the weight does become a factor, then you're probably thinking of power transmission lines, and in that scenario you can consider the tradeoff for seriously large amounts of power. I can imagine a small refrigerated tunnel containing a high-temperature ceramic semiconductor and carrying extremely large amounts of electricity with very little lossage.

Ummmm, dude, NASA is the one setting up the grant. That would imply that they're thinking about using it in spacecraft, satellites, probes, etc. where weight is a huge fucking deal.

From TFA:

"This is a small step but a very significant one from our perspective, as we try to develop new technology that will help us as we send humans out from Earth and into space," said Jefferson Howell Jr., director of NASA's Johnson Space Center.
...
NASA hopes to outfit future spacecraft with quantum wires rather than heavier copper wires. Doing so could shave critical pounds, which would save money on fuel and, ultimately, allow the craft to go farther into space.
...
Some engineers have also talked about building a 62,000-mile-long tether made of nanotubes for a space elevator that would carry astronauts and cargo into orbit.

Sorry, but you missed the point by about a lightyear.

Re:Further strains on my loyalty to my alma mater?

[pauldy]

Why answer a poster effectively refuting your original post with statements that make even less sense than the ones you lead off with? You do realize superconductive materials given their temperature instability would actually complicate the circuitry vs. simplify it right?

I will close with RTFA, RAFPB, LIUIFG, GAC, and see if you can figure out how this effects circuits given P=I^2R and why the over all stability of the circuit is effected with superconductive materials. This isn't some entertainment sh

This post made me very happy...

[Cytlid]

...in that I'm always picking on a buddy who works for LANL.

Now I can say (already have actually):

"you're a few nanotubes short of a meter!"

I wonder...

[RM6f9]

I wonder if there might be any help to be had with the seeding or growing process using properties involving electrical charge, magnetic fields, or some combination of the two to assist with selection and alignment...

Other uses

[bill_kress]

You could use such a wire to suspend a system of plates that would counter-revolve within your gigantic ring-shaped world to provide changing day and night zones.

A small ball on the tip of a strand repelled with a magnetic field would make a great sword/cutting tool.

Warnings for experimenters: Don't try to pick them up with your bare hands and watch out for sunflowers.

60 times better?

[Jherico]

As far as I know conductivty is a function of the cross section of a wire, which scales linearly with weight.

So 10 times better at 1/6th the weight should be the same as 60 time better as copper, or that it conducts the same as copper but at 1/60th the weight. Or 20 times better at 1/3rd the weight. Who's deciding this? I feel like I'm reading an article on futuristic wiring technology, but can't be trusted to deal with any number or fraction that involves a number larger than 10. Fuckers.

Re:60 times better?

[pavon]

The point is that given two wires with the same cross sectional area the quantum wire will be 10 times better and 1/6th the weight compared to the copper wire. It wouldn't make much sense to compare wires of different sizes as you suggest.

Re:60 times better?

[the_pooh_experience]

Actually, I believe weight scales as the square of the wire cross-section:

weight = mass*gravity
mass = density*volume
density is simply a material parameter, so assume we are comparing two wires of the same material
volume = length*pi*radius^2

However you can not treat CNT with the same simple analysis of something such as copper. CNT are sort of like hoses (empty on the inside, having a matrix of carbon on the outside). I assume that it is not 10* better than traditional copper cables, but rather 10

Try test equipment

[slapout]

Seems like a lot of money for a little wire

You've obviously never priced oscilloscope probe wires before. :-)

here is some of the wire:

[roman_mir]

it's right here:


- see it?

Re:here is some of the wire:

[Bearpaw]

it's right here: - see it? Excellent work! And your method is so easy to use that we've already adapted it to our own uses. For instances, your $11 million check is here:

Don't spend it all in one place!

even BETTER

[hoyboy9]

I'm a current Rice student, and one of the running jokes about all this nanotech stuff here on campus came from our student newspaper writers. Take two bucky balls, and one long nanotube, and fuse them together with a few bonds and you get: PHUCTANE All the students in orgo were completely phuc'ed after that.

in 5 years' time

[Zog The Undeniable]

Bill Gates will have his heated driveway recabled with this stuff.

What's the bleepin' point!! ??

[Ancient_Hacker]

" 10 times better than traditional copper cables at one-sixth the weight." Writing "10 times better" is mighty misleading. If a superconductor is "1", and copper is "0.95", then this whizzy new wire would be 0.995, only 4% better than copper.

And the weight of copper is rarely a problem.

Sorry to bring facts into this...

Rarely a problem?

[SuperKendall]

And the weight of copper is rarely a problem.

Unless you're sending stuff into space.

I can't think of anyone who might want to do that offhand but... wait, who was funding that again?

Sorry to bring the full set of facts into this.

Re:Rarely a problem?

[Ancient_Hacker]

>>And the weight of copper is rarely a problem. >Unless you're sending stuff into space. Sending stuff into space *is* mighty rare. And one might estimate copper makes up somewhat less than 1% of the weight of the ISS. Much bigger weight concerns are the continuing need for several pounds of water per person per day. Figure out a way to dehydrate wather and then you're onto something.

Re:Space elevator just a few months away!

[HermanAB]

Actually, it is easy to get into space. You just need to stand still and let the earth move away from you.

Re:Space elevator just a few months away!

[Anubis350]

still relative to what may I ask? :-P

Re:Space elevator just a few months away!

[HermanAB]

Just gimme a space anchor...

Re:Space elevator just a few months away!

[HermanAB]

In space the problem is not a lack of propulsion. The problem is a lack of brakes. If you can figure out how to stop, then you don't need propulsion - you just wait for the place you want to go to, to come to you.

In Star Trek, space is sticky. When a spacecraft shuts its engines down, it comes to a stop. If that was true, then space flight would be very easy, since everything is moving at enormous speeds, so if you want to go somewhere, just stop at the right moment and wait a while.

Re:Space elevator just a few months away!

[HermanAB]

"Say your in a spacecraft and you keep adding speed via rocket or something. How come you never make it to the speed of light? "

Your mass keeps increasing as your speed increases, because your kinetic energy increases and e=mc^2.

"There is nothing to stop you, you are adding an action, so how come you don't hit C or beyond?"

Your mass goes to infinity - that'll keep you.

"If you are moving faster than the speed of light (theoretically possible)"

No it isn't, see above.

"the shearing point (think of scissor

Re:Rice contracted WTF?

[quarkscat]

NASA HAS contracted Condi Rice to build a quantum wire 1 meter in length. Four years is plenty of time for her to pull a carbon thread out of her ass. And like the old fable, maybe she CAN teach that horse to talk.

Just like Haliburton, Condi is looking for that "brass ring" called the no-bid, sole-source government contract. You cannot really expect her to get by on the $250K USD per year that being Secretary of State pays. She has ritzy dresses and matching shoes to buy.

Besides, don't you think that

Re:Rice...

[Rei]

That's funny; when I read it, I was picturing a "Rice Rocket". Except a literal rocket, overdone in the same way Rice Rockets are concerning cars. You know, a couple oversized "Type-R" stickers plastered on it, half a dozen jumbo fog lights, a set of delta-wings tacked on for no good reason, etc ;)