Scientists Create Room Temperature Superconductor

StarEmperor writes "A team of Canadian and German scientists have fabricated a room-temperature superconductor, using a highly compressed silicon-hydrogen compound. According to the article,"The researchers claim that the new material could sidestep the cooling requirement, thereby enabling superconducting wires that work at room temperature.""

Room-pressure?

[atomicthumbs]

Is it also a room-pressure superconductor?

Re:Room-pressure?

[Zymergy]

NOPE. Do not pass Go Do not collect $200.

"Instead of super-cooling the material, as is necessary for conventional superconductors, the new material is instead super-compressed. The researchers claim that the new material could sidestep the cooling requirement, thereby enabling superconducting wires that work at room temperature."

Re:Room-pressure?

[Chris Burke]

Rats. Though at least hypothetically, it seems like it would be easier to design a containment for a high-pressure superconductor that requires minimal energy to maintain versus a low-pressure one. You can design a pressure vessel such that the pressure only escapes via small known locations (any valve or seal), whereas cold always escapes in all directions. So there still may be practical advantages to this discovery.

Though in any event characterizing the behavior of high-pressure materials is valuable.

Re:

[LiquidCoooled]

Once compressed and held inside a silicon (or other) wafer isn't it feasible that it will retain its shape and pressure and properties?

This sidestepping means you can take it out of the lab without having it tethered to a fridge or anvil.

Re:Room-pressure?

[elronxenu]

IANASE (I Am Not A Superconductor Expert), but that sounds reasonable. There will not be superconducting wires of this stuff, at least no wires longer than microscopic scale.

If scientists can figure out how to make transistors from this stuff and use it to link those transistors together inside a chip then we might get CPUs which can massively exceed current clock rates.

The huge disparity between on-chip clocks and bus/memory clocks will increase the pressure on Intel and AMD to push as much circuitry on-chip as possible. The practical limit on that may turn out to be cooling requirements - how much heat is generated and needs to be removed from the chip.

Re:Room-pressure?

[Doc Ruby]

I don't see why superconducting wires of these silanes couldn't be kept pressurized by containment inside a fullerene jacket, at macroscopic lengths.

Once superconductors don't require huge apparatus for cooling or even pressure, I expect labs will make superconducting semiconductors [google.com] less exotic.

Re:Room-pressure?

[inKubus]

What if they can build a long one with a carbon nanotube lattice around the outside, which self-compresses when streched (sort of like one of those Chinese finger-traps). Then you could have a material which becomes superconducting when you stretch it, say between two telephone poles or something.

Re:Room-pressure?

[Alsee]

The huge disparity between on-chip clocks and bus/memory clocks will increase the pressure on Intel and AMD to push as much circuitry on-chip as possible.

Yes, but will it increase the pressure enough to achieve superconductivity?

-

Re:Room-pressure?

[SnowZero]

400 GPa [nasaspaceflight.com]

Re:Room-pressure?

[noidentity]

whereas cold always escapes in all directions

Cold is not a thing, it is the absence of something (heat). Heat, on the other hand, exists, and enters from all directions.

Re:Room-pressure?

[Gewalt]

Cold is not a thing, it is the absence of something (heat). Heat, on the other hand, exists, and enters from all directions.

Heat is not a thing. Thermal Energy, on the other hand, exists, and dissipates in all directions. (Heat is defined as the dissipation of thermal energy)

Re:Room-pressure?

[Wonko the Sane]

Cold is not a thing, it is the absence of something (heat). Heat, on the other hand, exists, and enters from all directions.

Heat is not a thing. Thermal Energy, on the other hand, exists, and dissipates in all directions. (Heat is defined as the dissipation of thermal energy)

Thermal energy is not a thing. Molecules do, however, have kinetic energy which they tend to partially transfer to other molecules with less kinetic energy when they randomly collide.

Re:Room-pressure?

[rubycodez]

kinetic energy is not a thing but a property dependent on inertial reference frame of observer

Re:Room-pressure?

[Wonko the Sane]

It's turtles all the way down

Re:Room-pressure?

[rubycodez]

yup, and I tell ya what, the legs o' them broad-backed world supportin'turtles is good eatin!

Re:

[inKubus]

An inertial reference frame is not a thing but it IS a concept.

Re:

[Yvanhoe]

The observer is a lie !

Re:

[dintech]

Hold on There, there's No Need to Capitalize on the Situation.

Re:

[jpellino]

"You can design a pressure vessel such that the pressure only escapes via small known locations (any valve or seal), whereas cold always escapes in all directions. "

Feh. You were obviously not brought up in my house. Cold goes only through the open door. Ask my father.

(And yes, we both know that cold doesn't go anywhere, heat does...)

Re:

[JonathanR]

If there's a cold wind whistling in through the open door, then certainly cold is coming in.
Since convection is one of the three heat transfer mechanisms, then movement of cold mass and subsequent dilution with a warmer mass, viz. cold coming in, is a valid description of heat transfer.

How much pressure?

[Gorimek]

It doesn't say how much "super pressure" is.

If a power cable at the bottom of the ocean is under enough pressure, it could be very useful.

Re:How much pressure?

[DTemp]

The story I read said 50GPa. Which is around 7-8 MILLION PSI. We're talking a whole boatload of pressure here. 50GPa is the minimum, the superconductivity is maintained at higher temperatures at around 120GPa (or 20 million psi).

Re:

[Anonymous Coward]

I think we probably have enough silicon. It is about 25% of the earth's crust by mass.

Re:Room-pressure?

[moderatorrater]

No, but I suspect that this will still be a huge breakthrough, because we're generally better at keeping things pressurized than at keeping them cold. We have many, many static, high-pressure system with high reliability, but not that many super-cooled ones because cooling requires active energy expenditures.

Re:

[AlecC]

But if it does go wrong, things could be bad. Superconductors are laready prone to explosive failure if a superconductor suddenly ceasews to superconduct. If that is inside a very high pressure vessel, the available energy from a destructive malfunction is frightening : Mega-amps of electicity and giga-pascals of pressure suddenly being unleashed in the wrong place.

Re:

[bdjacobson]

But if it does go wrong, things could be bad. Superconductors are laready prone to explosive failure if a superconductor suddenly ceasews to superconduct. If that is inside a very high pressure vessel, the available energy from a destructive malfunction is frightening : Mega-amps of electicity and giga-pascals of pressure suddenly being unleashed in the wrong place.

Gives a whole new meaning to the phrase "you let the magic smoke out".

With this new technology, I imagine a lot fewer people will be alive to say this. Overclockers beware-- these chips will let YOUR smoke out too!

Re:

[gumbi west]

The real question is, is it suitable for stretching into cables that can carry a reasonable amount of current. Without that, it's just a parlor trick.

Re:

[deek]

Superconductivity is not only useful for power distribution. It can also be used for energy storage and high strength magnetic fields. There still may be a fair few practical uses for a high pressure superconductor.

Applications?

[Anonymous Coward]

I know Michael Flynn, in his novel Firestar [amazon.com] had some of his whizbang young people contributing to a new space age by developing superconductors that work at room temperature, but he never said what exactly superconductors do in space travel. What exactly new technologies will we see built on this?

Re:

[Anonymous Coward]

MagLev.
The biggest issue right now in most maglev is the energy required to cool the wires in the tracks.

Re:Applications?

[mbessey]

Super-strong electromagnets are one application of current superconductors. There are a number of uses for such magnets in space, from reaction engine control, to ion thrusters [wikipedia.org], to magnetic "sails" [wikipedia.org], to gathering fuel for a Bussard ramjet [wikipedia.org].

Magnets can also be used to direct dangerous radiation away from ships and the crew, in a phenomenon similar to the cause of the auroras [wikipedia.org] that light up the night skies here on earth.

Re:Applications?

[Ungrounded Lightning]

Also: Mass-driver reaction engines. (Electric catapults using asteroidial debris for the "exhaust".) They work much more efficiently if you don't have resistive losses in the wiring and coils. (But rapidly changing the current through a superconductor is also problematic...)

Re:

[Lord Ender]

When the Earth's gravitationally pole flips once again, humans will have to carry super-conducting electromagnet umbrellas with them to avoid the mass-extinction causing radiation.

Re:Applications?

[deimtee]

Run a few loops of it around the equator, put a big enough current through it and you could put Magnetic North on top of True North, where it bloody well should be.

Re:Applications?

[Goaway]

Actually, it is quite hard to cool things in space, if they generate any kind of heat. You can only radiate heat away - conduction and convection won't help you.

Umm...

[linuxboredom]

So, how exactly is this a good alternative to colder superconductors? Pressure is often more expensive to safely maintain. Not to mention the fact that SiH4 autoignites at room temperature.

Re:

[dotmax]

That's a good question. As they say, "more research is indicated". It might be a dead-end, and it might be a gateway to something fabulously useful.

On an grim note, i happened to notice a distinct lack of American presence in this announcement. Seems to be a Canadian/German thing. Y'know, that science stuff the US is running away from at full tilt (i work at a large US atom smasher that, like a *lot* of other Big and L'il Science Thangs, got a major budgetary wedgie this year). At least i still have

worth a read

[Anonymous Coward]

You might find this [american.com] worth a read in considering the future of science in the US.

Re:worth a read

[CrazedWalrus]

Thanks for the link. It's a great read.

This just reinforces my idea that the internet came along at an absolutely perfect time to save America from itself. As these wonderful-sounding yet completely impractical ideas continue to pervert and destroy our academic institutions, the internet will necessarily play a larger and larger role as an alternative to "traditional" learning venues.

Many of us technologists are mostly self-taught when it comes to our professions -- particularly sysadmin and programmer types -- because the technology was available and the communications infrastructure just adequate that we were able to get the learning tools we required to equip ourselves for our career. Many of us then went to school already knowing the better part of what was necessary for our careers.

I propose that people like this were the pioneers of internet learning, and that, as academic institutions continue down their strictly regulated politically correct paths to irrelevance, people who really want to learn will do so online in the world classroom.

I'm not saying that's ideal. I'm just saying that, if special interest groups and politicians looking for a soundbite get their way (and they will), it might be the only way, short of leaving the country altogether.

Re:

[inKubus]

The problem is most people don't finish college, therefore the politicians are doing what the masses want. The problem isn't the politicians--it's the masses.

Re:Umm...

[pla]

So, how exactly is this a good alternative to colder superconductors?

Because you can maintain a given pressure without the continual input of energy. Temperature (in either direction) has the annoying habit of doing its best to match that of the ambient environment.


Not to mention the fact that SiH4 autoignites at room temperature.

In the presence of oxygen, yes... Fortunately, you can buy small glass containers that maintain an anoxic environment at four for a dollar, under the name "light bulbs".


Pressure is often more expensive to safely maintain.

Don't think in terms of working with compressed gasses - Think of something more like a propane tank, where once you have it in there, it just sits there and doesn't really take a whole lot of maintenance. Keep it out of the sun and avoid mechanical stresses, and it will stay compressed and not do nasty things like burning/exploding for decades.

Re:

[gardyloo]

Because you can maintain a given pressure without the continual input of energy. Temperature (in either direction) has the annoying habit of doing its best to match that of the ambient environment.

Pressure has that annoying habit, too. After all, nature always likes to smooth out gradients of any sort. We just know how to deal with gradients of pressure a little more reliably than with those of temperature.

Re:

[gardyloo]

I didn't say it took energy to maintain a pressure. Neither does it take energy to maintain a temperature difference. That's what thermal insulators are for (just like solid metal or glass is a pressure insulator). It's when there's a breach in your pressure container that it takes energy to maintain pressure, just the same as when there's a breach in your thermal container.

Also: I understand that silanes are VERY toxic.

[Ungrounded Lightning]

Not to mention the fact that SiH4 autoignites at room temperature.

Also: I hear silanes (beyond n=1) are VERY toxic.

Back in my undergraduate days my chemistry teaching fellow was doing research on them. He claimed that the ones he was working on were so toxic that if you could smell them you had already exceeded the fatal dose.

(Now he might have been feeding me and the rest of the class a line of bull. But I wasn't about to argue with him. It WAS his thesis project, which implies that he should know what

Room temperature superconductors?

[Kaz Kylheku]

Like Leonard Bernstein, for instance?

Re:

[drwho]

Bernstein put the orchestra under immense pressure.

I don't believe it

[barakn]

Really.. I'm not just saying that.

Re:

[barakn]

Or maybe I do believe it. It's fairly hard to get synchrotron time if you're a crackpot. The article is sparse on details though, especially the pressure used...

In related news

[427_ci_505]

Researchers in Fairbanks, Alaska have just created a room temperature superconductor.

Re:In related news

[Surt]

Oh how good life would be if we only needed to reach fairbanks temperatures for superconductivity.
(Current best is a little worse than -300F, and fairbanks is not quite so cold, with a record of -66F).
So if they invented a room temperature superconductor, the world would in fact be quite thrilled at such a major breakthrough.

Re:

[khallow]

Fraid not. Turns out the researchers didn't actually get to [slashdot.org] room temperature.

obviously beer drinkers

[oddtodd]

the scientists, that is...

Its a bomb

[slashdotlurker]

Silane explodes with considerable violence on exposure to air. Plus, how are you going to put conductors under great pressure ? The main attractiveness of super conductors lies in long distance electrical supply lines. Unless they come up with a way to hermetically seal the "wire" over distances of hundreds of miles with a seal that can withstand high pressure compressors dotting the landscape (unlikely), this very interesting advance will remain just that - very interesting.

All not counting whether it is more energy efficient to run superconductors with energy hog compressors or to just stick to what we have, hopefully realizing practical room temperature superconductivity.

Re:Its a bomb

[pushing-robot]

Silane explodes with considerable violence on exposure to air

Cool, I get to mark two things off my Star Trek checklist in a single day:

* Room-temperature superconductors
* Computers that explode violently

Re:

[Torvaun]

It'd put evolutionary pressure on hicks to not shoot at them. It's a lesser victory, but a victory nonetheless.

Re:Its a bomb

[evanbd]

Silane explodes with considerable violence on exposure to air.

The best part? It's only *mostly* pyrophoric in air. *Sometimes* it waits a little while and accumulates a nice big cloud first, rather than flaring the instant it starts leaking.

Re:Its a bomb

[shotfire]

High voltage is already 'transmitted' in pressurized bus work. The bus work is pressurized with SF6 gas and is regularly used with voltages up to 500kV. This is common in Transformer Stations and other high voltage equipment (breakers, etc). You can come within 3' of a 500kV bus that's pressurized in SF6 (you can theoretically touch the outside of the bus work too, but I wouldn't). Unfortunately it's not economically feasible to do this over long distances. SF6 in itself is not toxic to humans, although it has a nasty habit of displacing all the oxygen in your vicinity. The by-products created when electrical arc occur within the SF6 gas are extremely toxic.

Re:Its a bomb

[Wonko the Sane]

Plus, how are you going to put conductors under great pressure ?

1. Make a wire of the material.
2. Clad material with a metal coating at high temperature.
3. Wait for the cladding to contract as it cools.

It's like the old metal shop trick where you get a red-hot brass washer that barely fits on a dry-ice cold steel rod and put them together.

Re:Its a bomb

[rcw-home]

1. Make a wire of the material.
2. Clad material with a metal coating at high temperature.

Said material melts at 88 kelvins. It'd be like galvanizing an ice cream cone.

Re:Its a bomb (B-field)

[dpilot]

About 20 years ago I watched them building a silane bunker where I worked. What a blast, figuratively speaking. Several layers deep of woven re-bars, zig-zag re-bar stitching between the layers. Concrete walls poured around them 1.5+ feet thick. Weak roof - any blast was supposed to be directed upward. A fun construction project to watch, whenever one had to walk past.

Incidentally, just how much magnetic field can this superconductor take. Temperature is only one Achilles heel of superconductors, the o

Imagine the weapon capabilities?

[PC and Sony Fanboy]

If I was playing civ, then this would be a pre-req for some sort of crazy future weapon.

Please hold your breath and run...

[Detritus]

Silane is pyrophoric and boils at 161 K. It may be a while before this leads to practical results.

Re:Please hold your breath and run...

[nonsequitor]

Silane is pyrophoric and boils at 161 K.

So you're saying it's vaporware?

Re:

[mother_reincarnated]

Just think of the cool failure modes! Queue the hypersonic jet of solid silane sublimating a second later into a raging inferno...

Re:

[chillax137]

It boils at 161 K at atmospheric pressure. Increasing the pressure increases the temperature at which the material vaporizes.

Re:

[shrikel]

Silane is pyrophoric and boils at 161 K at natural air pressures.

Obligatory room-temperature Tick quote

[Mr. Bad Example]

Egad, man! What's the point?

Superconducting Monster cables?

[PseudoThink]

So how long before we get to pay several hundred dollars for high-pressure, superconducting HDMI cables that take our HD viewing to the "next level"...and also spontaneously ignite if they are chewed on by the family pet?

Easy step now

[bluefoxlucid]

The hard part's done: We found a supercompressed gas (boiling point -161F) that superconducts. The next step now involves finding something electrically similar (think lead oxide + aluminum versus iron oxide + aluminum. Ignite iron oxide + Al and get Aluminum Oxide and iron and heat; ignite lead oxide + aluminum and get deadly lead gas + aluminum oxide + about 50 times more heat). Find the right chemical properties (solid until 500C?) on an electrically similar compound and you got yourself a deal.

Hot - I mean - Lukewarm Damn!

[jpellino]

This was some sort of holy grail, ne?

Now they just have to solve the pressure problem...

Vernacular change?

[Itninja]

So, lets say this eventually becomes a common technology (doubtful, but lets pretend). When do we get to stop calling them 'super'conductors? When the super becomes the common, is it still super? Like the evolution of memory classification in DOS. Before the advent of the NY kernal, I spent considerable time trying to remember the difference between conventional, extended, expanded, upper, and high memory. I think the main reason DOS gave way to Windows was Microsoft ran out of superlatives....

Re:

[Chmarr]

"Superconducting" means "you can't get any more conductive than this". So, there's no problem.

Re:Vernacular change?

[Chris Burke]

So, lets say this eventually becomes a common technology (doubtful, but lets pretend). When do we get to stop calling them 'super'conductors?

Never, because the physics of super conductors is different from regular conductors, and regular conductors are never going away. There are many, many circumstances where having resistance is necessary, and for that you need a plain-ol' conductor. Also I think we're safe from creeping-superlative-itis because you pretty much can't get more "super" than "effectively zero resistance".

And what's so hard about remembering all the types of DOS memory? "Conventional" was the kind that you never had enough of to launch your games. "Extended" memory was a baroque and stupid way of accessing all the extra memory you had that the chip couldn't address directly. "Expanded" memory was the same thing, only different. "Upper" memory was the memory your chip could address but refused to let your games use. And lastly "high" memory is when you were editing your config.sys autoexec.bat to get more conventional memory but you got distracted thinking about how funny it would be if .bat files were like, actually bats that flew around in your computer, and you forgot what the line was you just deleted, and your game never runs again.

I guess we need to update the "Holy Grail"...

[Dice]

OK, so previously a room temperature superconductor was considered a "Holy Grail" of science. However, as others have pointed out, this one won't be particularly practical since it requires large pressures to operate. We need to update the stated requirement for Holy Grail status as "STP superconductor".

This is NOT room temperature superconductivity!

[Anonymous Coward]

I'm holding TFA (Science, 14 March 2008, pp. 1506-1509). The highest critical temperatures they observed, regardless of pressure, were around 17 Kelvin (between 96-120 GPa). These are interesting results because they are among the few measurements available to shed light on the behavior of dense hydrides at these pressures, and these materials might, if better understood, one day allow a room temperature superconductor to be made. This, however, is not it.

Re:This is NOT room temperature superconductivity!

[Anonymous Coward]

Thanks for looking up the original paper (DOI: 10.1126/science.1153282). The EETimes reporter seems to be terribly confused.
The money quote from the paper:

On cooling, a typical metallic behavior of the resistance was observed and eventually becoming superconducting (SC) at Tc {approx} 7 K (Fig. 2B). Upon further compression, the sample became completely opaque at 76 GPa, and Tc increased, with pressure up to 17.5 K at 96 GPa and 17 K at 120 GPa (Fig. 2C). At higher pressures, Tc decreases to 8.8 K at 165 GPa and is then likely to increase again to 11.3 K at 192 GPa (Fig. 2C). The behavior of Tc between 90 GPa and 120 GPa is suggestive that higher values of critical temperature of superconductivity may be possible. However, uncontrollable change of pressure during sample loading (20) prohibited us from studying this regime in detail.

Damn you samzenpus

[vikstar]

God damn you for the headline "Scientists Create Room Temperature Superconductor". I almost fell of my chair in excitment. Then my climax was rapidly stolen when I read that it required high pressures. Next time, try to replace typical news sensationalistic headlines with pertinant headlines. In this case "Scientists Create Room Temperature but High Pressure Superconductor".

Re:

[Nimey]

You mean you don't automatically assume "sensationalism" or "submitter/editor got it wrong" when you see a Slashdot article? Especially one dealing with science.

You're newer here than I am.

Re:

[BoChen456]

Its worse, correct headline is "Scientists increase temperature of superconductor by adding great pressure, thinks its possible to get room temperature superconductor by adding even more pressure (Even though there is no way to generate that pressure yet)."

Re:Damn you samzenpus

[kravlor]

Amen.

I work in nuclear fusion. One of the things we lust after in my field of research is more efficient superconducting magnets. Hell, even getting up to liquid nitrogen temperatures would be amazing for us. In the meantime, we're stuck with using liquid He and associated cryogenics, plus extra nuclear shielding around the $$$ SC coils.

Oh well. I thought we might have had something truly wonderful going with this one tonight, but it's just false advertising... (sigh)

pressure, temperature...

[bcrowell]

The group in Germany that did the experimental work specializes in doing measurements of pressures of ~100 GPa. It looks like they use diamond anvils, http://www.mpg.de/bilderBerichteDokumente/dokumentation/pressemitteilungen/2004/pressemitteilung200408022/index.html [www.mpg.de] . So, okay, this would be a really earthshattering development if it led to superconductors that work at room temperature and at ordinary pressures, but it sounds like that may not happen. We already have superconductors that work at liquid ni

room temperature still requires cooling

[drfrog]

given the rising global temperature... it seems logical that we will still need some sort of cooling to keep rooms at 'room temperature'

at least anywhere south of the artic circle

hey...

[serbanp]

is that an early April Fools or what?

Buckytubes as containers?

[otis wildflower]

I wonder if these molecules would fit within carbon buckytubes, and if those tubes could withstand the pressure required for room-temp superconductivity without exploding into organic compounds?

Re:

[ndelta]

GET OUT OF MY HEAD!!!!!!

Simple answer.....

[edwardpickman]

give it my job. There's more than enough pressure.

There is both more and less than meets the eye

[randolph]

The more is that the researchers have shown that silane turns into a metal at very high pressures; while researchers have not managed to create metallic hydrogen, they have managed this. The less is that it's only a 17-degree Kelvin superconductor--not an extraordinary temperature--and the pressures involved are on the order of half a million atmospheres.

The original article [sciencemag.org] was published in Science on 14 March 2008; Vol. 319. no. 5869, pp. 1506 - 1509; DOI: 10.1126/science.1153282. Your local library can probably get you a copy; if you are at a university you may be able to access the online version.

Re:

[chuckymonkey]

I think you missed the point. Not Cool!

Re:

[secPM_MS]

The press release had essentially no information. The fact that they were using a accelerator X-RAY source clearly says that they were working with a diamond anvil cell. It would not be surprising if the pressures involved were in the Megabar levels. You would want to know what the transition temperature is for deuterated silane, as this would tell us if phonon modes were involved - classical superconductivity is phonon-mediated, while the cuprate high temperature superconductors involve very short range el

So what

[WindBourne]

This is absolutely awesome if they can get it into production, even in 20 years.

• Efficient motors (think electric cars and perhaps even airplanes and boats);
• Zero loss of power while sending it all over North America (or Europe, Asia, etc).
• Heck, we are looking at hitting coppers limits. If this comes to be, then the use of copper will decrease and we will see a drop in price of that. The amount of copper that goes into large motors is pretty big.
• Just thinking about it, it might even be used for electric storage.
• Maglevs might become practical.

Besides, think of where we were 20 years ago; roughly 20 years ago, physicists had found a way to increase the temp. Those wires are now being used for short distance tranmissions. This could change everything.

Re:

[Lewrker]

I'm just predicting a dupe on Slashdot in 20 years.

Re:So what

[cayenne8]

"This is absolutely awesome if they can get it into production, even in 20 years."

No doubt. Think of the awesome stereo cables you could make with these!!!

Superconducting speaker cables and interconnects....the audiophiles dream!!

No wooden knob needed.

:-)

Re:

[GumphMaster]

Surely we'll have to wait for directional, oxygen-free, hand-plaited, super-conducting cables that only come pre-cut in matched sets with superconducting power cables. Of course, such cables would be incomplete without solid gold plugs fitted by deaf vestal virgins and a name that gratuitously includes the words "Reference" or "Ultimate". My stereo is quivering in anticipation ;)

Re:So what

[Darth]

No wooden knob needed.

No, you'd still need the audiophile.

(i kid because i care... ok, you caught me. I don't really care)

Re:So what

[daem0n1x]

No way! The cold sound of a superconductor cable cannot be compared to that warm, round sound of a vintage copper cable.

Re:So what

[Rei]

Heck, we are looking at hitting coppers limits

Morbo voice: "Resources do not work that way!"

What is being talked about here is *economically recoverable reserves*. What is economically recoverable depends on two things:

1) Current prices. As prices rise, by definition of the term "economically", more reserves become economical. Typically increasing exponentially.

2) Technology. Technology improvements act as a counter to increasingly difficult to extract reserves. Improvements can outpace it, wherein prices drop, or be outpaced by it, wherein prices rise. Example: adjusted for inflation, oil today is cheaper than it was back in the late 1800s when it bubbled to the surface in Pennsylvania (as opposed to having to be driven up from miles underground in inhospitable locations)

The applicability of this to oil [daughtersoftiresias.org] and lithium [daughtersoftiresias.org] are discussed.

Re:So what

[WindBourne]

Guess I was wrong. Maybe not. A few others said that this REQUIRES this to under constant high pressures. If so, then this is pure research and will never go into dev/prod. But it sure would be nice to have something cheap and plentiful that does the trick. I really think that whoever figures out how to make cheap room-temp (or better above that) superconductor wire will have the hottest item of this century. That one item would impact nearly all aspects of the world. In fact, I can not think of any one invention that would have a bigger positive impact on us.

Re:So what

[FuzzyDaddy]

wouldn't it be far cheaper to run very high current on a small superconducting cable

Superconducting wires have a critical current above which they are no longer superconducting. Given the nature of the measurements alluded to in the article, they probably don't have a good idea of what that value is for his superconductor.

So even with superconducting transmission lines, you still have the incentive to up the voltage as much as possible to increase the power carrying capability of a single line.

Re:But...

[SQLGuru]

Combine the room-temp superconductor plus the motionless CPU cooler, throw in the fact that scientists success corrolates to beer (three stories from today), and you just might have colder beer.

Layne

Re:

[Hal_Porter]

Theoretically if you compressed the beer to 3 billion atmospheres it would taste cold, if I'm interpreting the article correctly.

Actually I found this article

http://en.wikipedia.org/wiki/Metallic_hydrogen#Discovery [wikipedia.org]

In March 1996, however, a group of scientists at Lawrence Livermore National Laboratory reported that they had serendipitously produced, for about a microsecond and at temperatures of thousands of kelvin and pressures of over a million atmospheres (>100 GPa), the first identifiably metallic hydrogen.[3] ...
The scientists were surprised to find that, as pressure rose to 1.4 million atmospheres (142 GPa), the electronic energy band gap, a measure of electrical resistance, fell to almost zero. The band-gap of hydrogen in its uncompressed state is about 15 eV, making it an insulator but, as the pressure increases significantly, the band-gap gradually falls to 0.3 eV and because the 0.3 eV is provided by the thermal energy of the fluid (the temperature became about 3000 K due to compression of the sample), the hydrogen may, at this point, effectively be considered metallic.

Even stranger it might be possible to make Metastable Metallic Hydrogen

http://en.wikipedia.org/wiki/Metallic_hydrogen#Fuel [wikipedia.org]

It may be possible to produce substantial quantities of metallic hydrogen for practical purposes. The existence has been theorized of a form called 'Metastable Metallic Hydrogen', (abbreviated MSMH) which would not immediately revert to ordinary hydrogen upon the release of pressure.

In addition, 'MSMH' would make an efficient fuel itself and also a clean one, with only water as an end product. Nine times as dense as standard hydrogen, it would give off considerable energy when reverting to standard hydrogen. Burned more quickly, it could be a propellant with five times the efficiency of liquid H2/O2, the current Space Shuttle fuel. Unfortunately, the 'Lawrence Livermore' experiments produced metallic hydrogen too briefly to determine whether or not metastability is possible.

Since it's ultradense hydrogen, I wonder if you could use it in a fusion reactor? The Wikipedia article says cautiously that 'increased understanding of the behavior of h