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Can someone explain why this is a big deal? The author cites that it doesn't need an explanation, but I definitely need one lol.



Conduct electricity with zero resistance. This has been possible at cryogenic temperatures (powers supermagnets, MRI etc) but running at room temperature _and pressure_ means in theory that you don’t need expensive support machinery. Has been the holy grail for the field.

If true, this specific case is only low current, but demonstrates such a thing is possible - almost certainly winning an instant Nobel Prize.


Does this mean there would be no heat waste? And devices like phones and computers wouldn't get hot?


Computers would still get hot, because the main cause of heat is not resistance in wires, it's that when a transistor switches with charge in the gate, you need to dump that charge, and when you do this it turns to heat.

They would get less hot, because there are plenty of transmission losses too.


People were arguing about this earlier (some claimimg the opposite) but I didn't see a conclusion. Do you have an external citation handy?


I was one of the people who said power is wasted in wires.

When the charged stored inside a chip needs to change (like go from high to low), that energy associated with the charge needs to go somewhere. Currently most of the charge is dissipated in the wire and some of it within the transistor.

If the wires have no resistance, the transistor will be the one dissipating the energy, not the energy simply disappears.

So technically both options are right, but my position is the “technically right, but practically wrong” position lol

That said if the interconnects are less resistive, the switching process becomes more efficient and less power will be wasted than the bare minimum required.


Ahh right. I didn't think of that. Thank you for explaining.


I wanted to add but my morning poop time was over so never had a chance to write this.

If you have two capacitors, say C1 and C2, and say their capacitance is both C.

Say C1 is charged up to 2V. The energy stored in that cap is 1/2 CV^2 = 2C.

Say C2 is not charged up.

The charge on C1 is Q = CV = 2C. The charge on C2 is 0.

Say suddenly you connect C1 to C2 via a lossless wire.

The charge on C1 and C2 must be equal before and after the connection since charge cannot be destroyed.

After the connection, the voltage on both caps will be equal, and the charge on them will therefore be equal.

Charge on each cap is 1C; voltage is therefore Q/C = V, V = 1V on both caps..

Now let's look at the energy on either cap. 1/2 CV^2 = 0.5C.

The combined energy on both caps are 1C. Where'd the energy go? We just said we connected the capacitors with a lossless wire, so it can't be dissipated there, and capacitors by definition cannot dissipate power.

The answer is that lossless wires cannot exist, and if you do the math more carefully, this time with real resistance and take the limit as R->0, you will see that the power-time integral of the wire (dissipated energy) will approach 1C.

The same argument can be made for integrated circuits; as your resistance drops, more and more of the portion of loss will be dissipated in the "other" sources of loss.

edit: superconductors are lossy at AC (but not as much as regular conductors get lossy at AC), and the capacitor connection is an AC phenomena so even with superconductors there will be a teeny loss even with superconducting wires. The rest of the loss will happen in other ways (EM radiation, dielectric loss, loss from capacitor resistance, etc)



We are very far from Landauer limit tho


I get it now. Thanks.


Where was the argument, may I see it?

I vaguely remember switching current and leakage current as sources of heat, but mircoelectronic circuits has been a while for me...


I believe they're referring to this comment thread I started:

https://news.ycombinator.com/item?id=36881808&p=2#36884542


One of the biggest use cases (for superconductors that meet their requirements) would be long distance power transmission, where as much as 30% of the power is lost over long distances.

Essentially, (and very top level) you could produce 30% more power, without adding any more production capactity.


HVDC has losses of more like 3%.


It is my understanding that computers would still need to somehow dissipate energy when they perform irreversible computations, and that will turn into heat. E.g. when you compute the AND of two bits, then the result is only one bit and you have to dispose of the remaining bit either as heat or as a garbage output signal.


That's a thermodynamic limit, but we're not even close to hitting that yet.

RTP superconductors still aren't going to magically make computers emit zero heat, though; there are other sources besides resistive losses. I was under the impression that other factors dominated, though a couple people responded yesterday to tell me that resistance is the primary source of heat. Not an expert in that area, would love for someone who does chipset design to clarify.


There's the rather non-trivial problem of actually manufacturing chips with the superconducting material.

But if that can be solved, then yes, it could make computing way more efficient.


Yes, among many other things.

There's many vast amounts of electricity wasted due to transmission losses. Magnets for fusion plants would become much cheaper.


and faster


Correct


Also, the clock speed of CPUs are limited by resistance and heat.

Both of those go to zero. We may see 100ghz CPUs and 3D stacked cpus with almost no need for cooling.


Wouldn’t you still get heat from current switching back and forth and transistors changing polarity?


At those frequencies, induction would be a huge headache.


Portable MRI would be a huge deal. We'd also see superconducting motors in electric vehicles, along with marked efficiency gains in every part of EV systems.

We could have a superconducting power grid with solar panels distributed across the planet. Superconducting batteries could give us grid level storage. It also reduces the cost of hypothetical fusion reactors, their magnets can be cooled with unpressurized water instead of liquid helium.

Calling this the most revolutionary discovery of the last hundred years isn't an overstatement. This will affect almost every industry and in ways that we can't even imagine yet. If this material is what they claim, it's going to be a new era for our species.


Those won't happen with the current magnetic field limitations. Ironically, this is the thing that makes me believe them more rather than less: it is plausible that if you find a material that is superconducting at room temperature that it isn't right away going to be ideal in every other respect, and it would have been very easy to fake that one too.


Right. Assuming this paper is true, just knowing that a superconductor with a critical temperature over 100C can exist at all is a huge leap forward.

It should lead to a huge push to understand the physics of this new material and building better materials with more useful properties


There are all sorts of neat things that you can do with superconductors now (toroidal inductor batteries, basically anything that would benefit from super strong coils like motors and magnets, novel electronics...) with the caveat that they are hilariously expensive to fabricate, and need a hilariously expensive cryogenic system built around them.

The cherry on top is that the materials and fabrication for this material seem relatively cheap.


People like to list technologies it would improve, like power transmission or MRIs, but I think it will be hard to predict what technologies are completely enabled by this, such as potentially fusion or quantum computing or things I don't even know about yet.


You could look at any of the other threads where that has been discussed to death


I asked a similar question and got the answer that we could technically put a ton of solar panels in the Sahara and use this new material to transmit that power to anywhere in the world (without losing any power). Currently you couldn't do that since transmission lines lose power over distance.


Unfortunately it's not the hoverboard from BTTF that i was looking for. :)


Could make cheap MRI and maglev trains, high-density electronics, quantum computers, fusion power, and many other potential applications.




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