Liquid Nitrogen Beats Air Cooling (Again) 199
joe094287523459087 writes "some guys used liquid nitrogen cooling via a cardboard tube to get a 20,000 3D Mark score. you can see the frost forming on everything - wouldn't the moisture from the condensation kill the board?" The Muropaketti guys had already done this with their microprocessor. Apparently the next step was to speed up their graphics card to match.
Fabulous (Score:4, Funny)
When can we expect this on fuel cell powered laptops?
Re:Fabulous (Score:2)
Not necessarily, if it's -196 C (Score:5, Interesting)
Re:Not necessarily, if it's -196 C (Score:5, Insightful)
Re:Not necessarily, if it's -196 C (Score:2)
Re:Not necessarily, if it's -196 C (Score:2)
How do we protect them and the wires? Silicon grease. Without that grease, 36 volts can burn and smoke a wet circuit board. Considering it works with hundreds of $20,000 fork lifts, I'd try this on your N2 powered turbochared motherboard.
Re:Not necessarily, if it's -196 C (Score:2)
(Sorry - my pet peeve; I go nuts when I hear about "silicon" breast implants or "silicone" chips)
somebody beat him to it (Score:5, Interesting)
What's so special about him getting 20372 by overclocking his P4 to 3916 MHz?
The article has a picture [muropaketti.com] showing that someone got 21504 by overclocking to 3998 MHz -- nine days earlier.
mostly tiny ice crystals from the fast cooling (Score:3, Interesting)
Unless they're venting vast quantites of boiling nitrogen into there though, it shouldn't be too bad. Plenty of hydrophillic stuff ariund should deal with that. A few sugar cubes in there, or some conc. sulphuric acid maybe!
Re:mostly tiny ice crystals from the fast cooling (Score:3, Informative)
Not the sharpest pencils... (Score:3, Insightful)
Re:Not the sharpest pencils... (Score:5, Interesting)
Re:Not the sharpest pencils... (Score:3, Funny)
And people complain about Jackass and Beavis & Butthead setting a bad example for our children?
Re:Not the sharpest pencils... (Score:4, Funny)
If you're stupid enough to do that, like this guy [darwinawards.com] , then you're well on your way to qualifying for a Darwin Award.
Re:Not the sharpest pencils... (Score:3, Interesting)
Heh, yup. I had to watch a friend in 4th year physics dunk his fingers into and out-of liquid nitrogen really fast a few times before I was brave enough to try it myself.
As advertised, the flash-boiled liquid nitrogen insulates your fingers for a fraction of a second. You can't keep doing it though, lest your tissue cool down too much, and who knows *exactly* how slow/fast you can do it without injury, and no-one was willing to try and find out
Re:Not the sharpest pencils... (Score:2, Informative)
We spent hours playing like this, and of the 20 of us in the class, not one was injured.
Re:Not the sharpest pencils... (Score:2)
Just proves that you can play with fire and liquid nitrogen at the same time.
Re:Not the sharpest pencils... (Score:2)
Re:Not the sharpest pencils... (Score:2)
It's just you. (Score:1)
Gloves worn during these experiments I think are more because of the other things that might get really cold while working with the lN2, or breakable...
Re:Not the sharpest pencils... (Score:2)
Even if that happened, it would take a while longer before you'd be in danger of loosing your fingers. You might suffer from some blistering or frost bite, but that would heal.
Liquid Nitrogen is actually used in direct contact with skin as a treatment for warts. It's not really that dangerous.
Frost everywhere (Score:2, Interesting)
I must be missing something, if someone could please fill me in...
Re:Frost everywhere (Score:5, Informative)
Re:Frost everywhere (Score:2)
Re:Frost everywhere (Score:1)
What's the point? (Score:2, Offtopic)
1.) The frost/condensation shorts out the board
2.) You run out of liquid nitrogen, and the board fries itself, locking up the game.
There is nothing like playing UT while worrying about filling up the liquid nitrogen. With my luck, I'd end up accidently pouring the liquid nitrogen directly on the board, causing it to fiercly boil, and I'd drop the dewar flask and get the shit all over my hands.
Besides, the blazing speed of the graphics will probably do nothing for me, so long as I have to deal with flaky lag on my broadband connection.
Re:What's the point? (Score:2)
Is there any reason? Nope. Looks like fun though. If I had the cash to waste on stuff like that, I probably would.
Re:What's the point? (Score:2)
Looks like they're trying to get to the number one position on the MadOnion 3dmark chart. This time they made it to second place. Next time maybe they'll break the record. Yay for team Finland!
Re:What's the point? (Score:5, Funny)
That would mean he is putting the nitrogen in the wrong place....
Re:What's the point? (Score:3, Interesting)
Re:What's the point? (Score:1)
Re:What's the point? (Score:4, Interesting)
I mean Moore's law still trumps overclocking any day.
Limiting factor (Score:5, Interesting)
We really need to see more memory bandwidth saving technology on GPU's. ATI pushed ahead a lot of cool things (early Z, occlusion culling, Z-compression, fast Z-clear), but it's not far enough. The Kyro/Dreamcast use tile-based deferred rendering rather than immediate mode, and the GameCube's GPU (designed by ArtX, which is now a owned by ATI) uses a 2 MB on-chip Z-buffer cache which alleviates the need to go to video memory every time they want to do a Z-test (which is typically at least once per pixel). Given, the Cube doesn't ever have to deal with a frame buffer bigger than 720x480, so a fixed size Z-cache is much more useful there.
On another note, I'd really like to see support for geometry amplification schemes (n-patch tesselation, displacement mapping, etc.) that work properly with stencil-buffer volume shadows.
Re:Limiting factor (Score:2)
Liquid N colder than air.. wow! (Score:5, Funny)
This is cool in some horribly over the top manner, but I think the last cooling using liquid nitrogen story a few months back covered it.
Liquid Nitrogen Beats Air Cooling (Again) (Score:5, Interesting)
That aside, Liquid Nitrogen might be a bit of overkill here. When properly coated, I'm sure the parts are safe from the damaging effecets of melting, but everyone needs to remember one thing, heat is the enemy, it's obvious that it would take quite a bit to get too cold.
Obviously there isn't a future in Liquid Nitrogen cooled computers, but take the idea back from the "weird science" to the new liquid/radiator idea. I do believe silent machines running cooler with liquid cooling, will become a new trend.
Lastly, why does everyone brag about their 3DMark scores? If you suck at gaming the extra pixels sure ain't gunna help ya.
Re:Liquid Nitrogen Beats Air Cooling (Again) (Score:3, Interesting)
As far as being too cold--as long as no thermal shocks are involved, I don't think there's such thing as too cold. I look forward to
Re:Liquid Nitrogen Beats Air Cooling (Again) (Score:2)
well...if you cooled the system enough, something in there would probably start superconducting, and while SC is very useful if you've planned for it, it could really screw things up if you hadn't (i.e. if your copper substrate suddenly loses all resistivity, that's gonna mess up your processor).
There's no (Score:2)
Re:There's no (Score:2)
Liquid Nitrogen Beats Air Cooling (Score:5, Funny)
Next Step for these guys... (Score:4, Interesting)
If you could do it right, and can afford the proper parts to build it. Create a high-power compressor, and have it pipe super-cooled fluids continually through both processors. Therefore, you don't have to pour/buy liquid nitrogen everytime you want these results.
The problem is that it costs a lot and is quite difficult to build a fast high-power compressor/cooler. If you guys can accomplish this, then I'll be impressed. Pouring liquid nitrogen onto stuff to keep it cool isn't really that exciting/impressive in the long run, since it is far to manual, and doesn't require much thought to come up with the idea.
I am curious though, does anyone know of more fancy coolers for the processor that work impressively but don't require constant manual addition of coolant?
Re:Next Step for these guys... (Score:2)
Re:Next Step for these guys... (Score:2)
1/2 the 3dmark tests not shown. (Score:4, Informative)
His ATI driver is also 6.13.10.6159, he should upgrade to 6193, major performance increase. You can get it over at rage3d.com [rage3d.com]
Impressive thou, Double my 3DMark [madonion.com] on a plain AMD 1800 with a ATI 9700.
Re:1/2 the 3dmark tests not shown. (Score:4, Informative)
Cooling (Score:1)
Actually ... (Score:1)
Avoiding condensation (Score:3, Interesting)
Now the only problem remaining is how to avoid condensation on the glovebox itself so you can see what's going on inside
LN2 and condensation (Score:5, Interesting)
Well--eventually, maybe. But what they've build is essentially the back half of a water distillation system. The water that condenses out of the air will be very pure, and have a very low conductivity. (The resistance of a 1 cm path through ultrapure water is on the order of 18 meg--that's ohms, not byes--so it probably conducts no more electricity than the plastic of the board.)
Yes, the condensate will eventually pick up contaminants, and at the edges of the cooled region where liquid water is free to flow you're likely to have problems. The solution would be to keep the entire mainboard in a dry environment. Seal it in a box with only an inlet for LN2. The little bit of water in the box will condense out (on the N2 fill pipe rather than the board if you remove a bit of insulation) and as the LN2 boils off, the box will be filled with dry, inert nitrogen. As an added bonus, this will help suppress fires.
Re:LN2 and condensation (Score:2)
I'll second that...
One of the most amazing trade show booth demos I've ever seen was a water distillation system. They had computer monitors running a demo while under water. I know the why and how, but still, just plain unnerving to see high voltage stuff working like it was dry.
Re:LN2 and condensation (Score:2)
Re:LN2 and condensation (Score:2)
Re:LN2 and condensation (Score:2)
I'd be careful about something condensing into the liquid nitrogen as it boils off. Like oxygen. Liquid oxygen may start to get concentrated over time into the mix and create an interesting condition known as rapid oxidation. Some people might call it combusion. Others may describe it as an spectacular explosion.
If liquid oxygen can set a highway on fire (to bad that famous tanker scene in Terminator wasn't O2, not N2,) imagine what it can do to a computer in the privacy of your own home.
Re:LN2 and condensation (Score:2)
Worth noting, definitely--but not likely to be a problem. As long as LN2 is flowing in to the box, and the box is not perfectly sealed any oxygen that was inside when the box was closed will be slowly flushed out. I imagine that most hacks assembled from /. posts aren't quite airtight, so the concentration of oxygen in the gas mix will decay exponentially with time.
Also, since only the GPU and CPU are directly cooled with LN2, the rest of the board will stay warmer, limiting problems with O2 condensation.
Captain Obvious on Line 1... (Score:5, Funny)
In related news:
Ice is colder than Steam
Touching hot things will burn you
You can skate on ice
Lots of fire will make things melt
The speed of light is very fast
Not frost (Score:2)
Re:Not frost (Score:2)
Re:Not frost (Score:2)
Re:Not frost (Score:2)
But, then I suppose you didn't bother reading my reply to his comment before writing yours, now did you?
Space Cooling... (Score:3, Interesting)
I guess you'd run into problems with cosmic radiation - but nothing a good dose of shielding wouldn't fix. Placement would also be an issue, couldn't just pin it to the back of the station...
Anyone know of any experiments along those lines?
Re:Space Cooling... (Score:3, Informative)
Yes, they do. They aren't experiments, they are in fact how the space station works. On the last mission they brought up 3 more ammonia radiators. [nasa.gov]
These work by taking water which runs past the electronics, exchanging that heat to liquid ammonia, which out the truss, and through these huge metal radiators which then radiate the heat to space. They have to use ammonia because the water would just freeze if it went through the external radiators.
More space station info... [nasa.gov]
Difficult (Score:2)
I don't have any good hard figures on this, but it seems to me that if you want to cool something down that near absolute zero, you're going to need something a bit more active than a big radiator. In labs here on earth that sort of cooling can only be done on a nanoscopic level, generally using lasers to slow down atoms.
Cold hard VACUUM (Score:2)
Vacuum happens to be an excellent insulator...
And when the station is in direct sunlight it heats up VERY quickly. You can expect temperature swings for something in orbit to go from freezing cold to burning hot - Often in the course of a few minutes.
I was involved at school in designing a small satellite (See cubesat.org for a general description of this class of satellite) - I was (fortunately) handling the radio board, and wasn't one of the thermal guys. I felt sorry for them...
During dark times, the satellite had to have small heaters to keep the batteries from freezing.
20-30 minutes later in the orbit, the satellite's problem would be overheating.
Re:Space Cooling... (Score:2)
That great big copper sink I mentioned.
Re:Space Cooling... (Score:2)
Radiation. How do you think they cool things in space?
It's a trade-off. In air, heat can be taken off by conductive transfer: heat goes from heatsink into air, then the air flows away. However, in air, radiative cooling is not as effective because the air molecules reflect the radiation in all directions, and some of it goes back into the hot object. In vacuum you have no conductive cooling but there's nothing standing in the way of radiation.
In vacuum, you want a heatsink where all the radiative surfaces face out into space (not toward each other like a conduction heatsink), and the material has a high emmissivity (silver, gold are often used).
Re:Space Cooling... (Score:2)
The thermos works to minimise all main energy transfers, the vaccum deals with conduction, the silvered surfaces with radiation etc.
For a good desc. of how a Thermos Works go here [howstuffworks.com].
Re:Space Cooling... (Score:2)
Many factor determine the speed of evaporation in space - primarily whether it is in the sun or not. In the sun it generally explosively boils away (nearly 250F) and in the dark it tends to freeze quite quickly.
My gut feel is that you'd get colder fast if you were wet in space, though it would be the least of you (or your cat's) problems at the time...
Safety first, kids! (Score:2)
Re:Safety first, kids! (Score:3, Insightful)
Now, if his fingers slipped and the cup of N2 fell over his hand, he'd be out of luck... Wearing gloves in that case isn't enough protection, because the liquid will just run down the glove, under the cuff of the shirt, onto the arm. The best thing to do is manipulate the N2 dewar with a long pair of tongs...
People have done dumber things before, like dousing their head in alcohol (to kill lice) then lighting up a cigarette...
Re:Safety first, kids! (Score:2, Redundant)
Moisture (Score:4, Informative)
I would think that you need to immerse a board in distilled water for some weeks or months to get actual damage. Fans, HDDs and other moving parts are a different story.
Physics? (Score:2)
Apparently it works on servers too... (Score:2)
I can hear it talkin' smack right now - "Bring it on you
21504 3DMarks (Score:3, Informative)
Liquid cooling (Score:3, Interesting)
It's really, really cold. [imagetechnology.net]
Re:Liquid cooling (Score:2)
Environmental Limits? (Score:3, Informative)
I looked around ati.com and intel.com, but couldn't find any specifications on what the upper and lower bounds are as far as temerpature is concerned. I recall seeing in most product specifications for electronic devices temperature limits, and I thought the lower was usually around -15 degrees celcius.
Or does the temperature of the chips ever get that low? Do they hit some kind of equilibrium that keeps them from reaching their lower limit?
Re:Environmental Limits? (Score:2)
In Other News (Score:3, Funny)
Telephone more effective than tin can and string
Umbrella proven more effective at staying dry than dodging raindrops
Mark
Damn it (Score:2, Informative)
Thermal shock (Score:5, Informative)
Also, if I remember rightly, the actual drain currents of the transistors goes UP because the resistance is going down (which is why you can overclock, of course.)Although the lowered temperature means the tracks will not be damaged, there may be other effects of the increased current density in longer term degradation of the die. If there is track necking anywhere, this might be a potential failure point.
You might also expect damage to the epoxy cladding of the graphics chips, as the contraction pulls the epoxy away from the filler. This could result in the epoxy eventually becoming porous and the system failing due to moisture penetrating the cladding, just like 6502s etc. used to fail before anyone realised that glass fibre filler could wick water in to the die.
The answer is to follow Seymour Cray and sink the entire system in cold fluorinert, using the total loss nitrogen system, or much cheaper dry ice, to keep the temperature at a sensible -45C or so. But that wouldn't be nearly so spectacular, would it?
This is all a bit like our local hot rodders who can't safely make it to the next town and back for fear the engine will blow up on them. Even so, it would be nice if Intel would release some of the data they doubtless keep on this sort of thing.
Watch a Thunderbird burn to death (Score:5, Interesting)
Not necessarily 300 degrees C (Score:2)
That said, even unpainted, a thermal camera can tell you, "Something is really heating up quickly... That isn't right..."
Capacitors usely go bye bye (Score:3, Interesting)
i'm not a chemist/physicist... (Score:2, Interesting)
Why this might not have worked (Score:2)
1) The specific heat of LN2 is much lower than water. This means that although you can get it cooler, you might not be able to get away enough heat to make a difference, or it might form a vapor barrier that prevents the LN2 for cooling efficiently. My guess would have been that you needed to actively pump it or agitate it. In fact, you probably can get quite a bit more cooling this way. If you've ever pour LN2 on your hand, you know that it doesn't really do very much (unless you cup your hand). Try this with boiling water and see if it hurts or not.
2) Since none of these components were designed to withstand low temperatures, there's a chance that something could have cracked. If there was something that had a vastly thermal expansion coefficient in the packaging and/or became very brittle (e.g. plastic), it could have just split open. Apparently that's not a big problem either. My bet is that they cooled it down pretty slowly before they turned it on.
I think the condensation issue is not as bad as one might think. It takes quite a bit of ions in order for water to become very conductive. It might be worthwhile to rinse your board in distilled water before trying this, but you probably don't have to bother. Just don't pour any salt on your board and it should be OK.
It's all about the home field advantage... (Score:3, Funny)
In other news... (Score:2, Funny)
The speed of light is found to be "really fast"
This water ISNT conductive ! (Score:2, Interesting)
if many of you know the celeron [tm somewhere], the ppga grid is visible from the top of the chip and I myself have had water covering every pin and moving it's way down the board just to test this very idea of water damage.
[peltiers - not NO2] = P
fyi no damage was incurred and I was damn suprised.
water != electrolyte (Score:2)
No, it's Slashdot. Expect the minimum. (Score:2, Funny)
Re:Yawn ... (Score:2)
High school physics? (Score:4, Funny)
Re:The title says it all... (Score:2)
I can say that....
Air is mainly nitrogen.
Gas at 20 deg c has 26 moles per decimiter cubed, I don't know what it is for Nitrogen vapor at -100 - degs.
I don't know the spacific heating capacity of air or nitrogen vapor (the amount of energy required to raise x moles of y by 1 deg) 'not quite high school physics, though I could work it out'
Ok so is fairly obvious, but there's a lot more than plain old 'high school physics' to think about.
Re:The title says it all... (Score:5, Funny)
Chemistry is just a mislabelled branch of physics
Re:The title says it all... (Score:2)
Chemistry is just the physics of electron shells (among other things). Biology is just the chemistry of organic molecules (at its heart anyway). Psychology is just.. well you get the picture. Physics is about finding the fundamental theories of the universe. Everything is physics by definition.
Of course, sometimes the link between physics and a higher level abstraction is poorly understood. For example, human behaviour is just the firing of neurons and so should be explainable by physics but we aren't even close yet.
I'm not suggesting that we get rid of these higher level sciences. Anyone who's programmed in assembler will realise that abstractions are important.
Re:The title says it all... (Score:2)
I used to program in assembler, and I wish more people still did. Actually my ideal programming language is now "C++, but don't use templates, polymorphism, or multiple inheritance - dont bother with the STL unless it's a very clear win - and profile your code and recode any super-hot-spots in asm". I guess what I really want rather than C++ is C with just a few C++ features - like member functions for structs, private declarations, operator overloading, and constructors/destructors.
My point is, abstractions sometimes go a bit too far.
Re:The title says it all... (Score:2)
Re:Pure water..... (Score:2, Interesting)