How We Get Down to 0.2nm CPUs and GPUs

After EUV (soft x-rays) we move to hard x-rays right? That's probably going to be hard to control.

@@Jaker788 Do we need to stick with photons? I realise they have a lot of nice properties but they aren’t the only particles one can use

@@mduckernz I'd think hard x-rays are hard enough to focus and control exposure. Maybe taking a page out of cancer radiotherapy, a linear accelerator that can accelerate x-rays, electrons, or protons in a focused manner is a possibility. I'm not sure how those particles work for photolithography, maybe new resists needs to be invented and modification of the LINAC machine.
I know there are some alternative machines not used that instead of using a large mask and exposing the whole wafer at once, work more like a CNC. Very slow but I think it was more accurate and precise? Maybe a LINAC could be focused to directly draw the design without a mask, probably extremely difficult, I don't know what's required to do that kind of precision and how the CNC type lithography machines work to begin with.

@@mduckernz Electron Beam Lithography is very interesting and can take us down to the atomic level. Look it up on Wikipedia. The only problem with EBL is that it's terribly slow, so slow that it is completely uneconomical unless someone can speed it up dramatically somehow. (Multiple beams is one idea that they are exploring.)

@@PremierSullivan Indeed, electrolithography (? Not sure if that’s a valid name for it, but you get the idea…) was the main approach that seemed viable to me.
Multiple beams sounds very doable, you just need to make sure they don’t pass too close to each other so they won’t repel each other and deflect their beams.
I also wonder whether you can do away with the beams, and instead use a modified resist and mask, and then bathe the silicon in electrons, treating them as if they were light.
The beams approach seems likely to work, and be effective, but yeah as with you I worry about the speed of it.

i'm actually not sure if that's really going to happen. power generation is ramping up exponentially with compute demand. datacenters don't seem to be more concern about power bills as much as they are concerned about squeezing the most compute possible. which means more power, as expensive as it is, is still cheaper than more compute.
GPUs are getting more power hungry primarily due to exploding compute demands, and the benefits are justifying the higher power bill.

My understanding is transistor density increase usually leads to power efficiencies improvement's however they can choose to focus on more performance or more energy savings

@@kicapanmanis1060 maybe, but from what i can see this is really been driven over the last 5 or so years by an explosive demand of AI compute that just keeps skyrocketing, which is mainly done on GPUs. this would explain why GPU power consumption has taken over CPU by such a large margin.

I think at some point near threshold computing may be necessary

bro the wide revolution has already been underway for a decade

Thanks Kim! Feel free to reach out if ever you're looking for sponsored content. A deeper look into the future of EDA in a chiplet and stacked world would likely go over very well

The Taiwan government representative is a member of the board of directors of TSMC, and the Taiwan government will never let TSMC be completely out of government control.

@@TriNguyen-he7xk I don't understand.

It's already very much like that in every field. Billionaires are so far removed from you and I, yet wield enormous influence over both their own industries as well as govt policy. These aliens are dictating huge swathes of our lives, not least limited to the majority of our time that we spend working to make them more money.
Worry not about the semiconductor foundries, they are staffed by ordinary people trying to work for a living like you and I. Worry more about the billionaires exploiting their labour and destroying the planet with overproduction, and the legions of other owners that amplify and venerate the billionaires.

@@TriNguyen-he7xk Pharaoh lives matter

@@TriNguyen-he7xk 😆😆🙉🙉

Artificial general intelligence. When computers can think better than humans and much faster, all bets are off. We could get a century of progress in a few years.

There is nothing beyond EUV. There is an upgrade the High NA EUV. Prototype machine are already being built but it would take a couple of years before it enters mass production. After that the industry would have to rely on multi patterning to keep scaling. This is of course the lithography side. The transistor side have a lot more avenue for squeezing density. And there is also the packaging side where a lot of research is going into increasing chip density.

And all having that awful "carpet" in the background... :)

As long as you can get access to the papers, I’d recommend just try to read a few, you pick things up through context clues pretty quickly (keeping notes of the acronyms on the side can also help). Also, review papers and the literature review sections of thesis papers tend to be quite comprehensive and can be a good place to start when looking at a new topic

Check my newsletter - www.more-moore.com

What's next, SporkFET?

mhmm pork fat

@@NarekAvetisyan Boba Fett!!!!

Forklift CertiFET

​@@NarekAvetisyan
Before I Forget 🤟

Good thing it's only a NAME, and not an actual physical dimension. It's meant to represent a theoretical planar transistor.

@@TechTechPotato I know, and that's like selling a 60kWh capacity car battery under the name "600kWh". And then imagine different manufacturers slapping random kWh numbers on their batteries to try to outcompete each other.
Misusing physical quantities with a well defined meaning as marketing names is beyond misleading.
Another such example that comes to mind is "resolution" of video projectors. Manufacturers market them as "4K", but it's actually just maximum supported input signal resolution and the projector then can only do a 720p image on the wall. The "native resolution" is hidden in small print.

@@ProjectPhysX Meh, it's representing the increase in density over a number of factors. Actual transistors size is just one of a handful such as, total gate area from design changes to GAA and such, space between gates, etc. You really can't just slap an accurate number anymore to actually represent the size so I'm not sure what you'd want.

@@Jaker788 of course you can put a precise number on it, and there is proposed standards to do so via transistor density. For example, count the number of transistors per mm², then calculate the average square transistor side length.

@@ProjectPhysX So you've got density down, but not quite. You have High performance cell libraries that are going to be less dense but handle more power, and there are at least a few cell libraries to choose from, all with different density and other specs. You've got ultra dense cell libraries for SRAM, stuff for logic, efficiency, custom ones for specific large customers. So even within a node there is no set density per area. There's leakage, power capability/density, efficiency, switching speed, doping materials, etc. There's a lot to a node that you just can't represent accurately.
There's so much to a process node. The current naming shows up a relative improvement over the last though, and that's pretty good without making a specific claim to density. For more specific specs you can look into their datasheet and get as much info as they're willing to show the public, which isn't everything and every cell library.

Dosent the Eldctron beam expose each layer like a televison tube writing each frame onto the screen instead of in one single burst with EUV-litho?

EUV has been a 35 year journey. Going beyond EUV has to have started today, and will take 35yr+. As far as I can tell, very little work is being done beyond EUV. High-NA sure, but that's mirrors, not sources.

@@TechTechPotato crazy ideas come every year, we can never know what the future holds. How Is the quantum computer working?

@@TechTechPotato but are there none competing processes in the works, that just have not matured yet? 🤔😲

There are small time research with alternatives. But there is no industry wide push to develop a technology beyond EUV. Without Industry wide coordinated effort to make something happen nothing will happen. The cost to develop something better than EUV is just to high that no single company can afford it. It has to be a team effort by everyone and even with everyone involve it will take several decades.

Perhaps divided by power consumption or something. Too many unknowns still 🤓🙃

MX Master

@@TechTechPotato thanks man, looks comfortable

In microtubes there would be the limit of the possible pumping volume of the coolant and the high purity needed.
Another problem would be the expansion of the coolant in high temperatures by making the chip silicone go skadoosh 💥
😂

All the tricks we've used pre-EUV we can apply to EUV, but they'll run out by the end of the decade probably.

@@TechTechPotato You say that EUV wont get replaced in your lifetime, in all probability, but I posit to you that with advancements in quantum computing and AI, there will be problem solving of thousands of years of all the worlds super computers of today, done in a few hours. Quantum Computers are not really useful right now, for the most part, as I understand it, but that is set to likely change starting in a couple of years. A.I. achieved, with the AI that won at GO, what was thought to be 10 years ahead of schedule at that time. And AI researchers don't even fully understand what it going on, that's how crazy its already getting.
Hopefully it doesn't end in disaster, but the advancements in intelligence itself would seem to be the thing that will allow us to go past EUV lithography, and doing so by the 2040s I'd guess.

Moving to Nanosheet allows for reduction for cell height because the fins are now sideways and you can just adjust channel width to reduce the cell height. Forksheet inprove this because the N channel and P channel are now side by side separated only by a barrier so two transistor are squeeze into a width of 1.5 transistor.

Anything that comes along will have to compete against 50+ years and trillions of dollars of innovation on day one.

@@TechTechPotato It just needs to be good enough in a specialized application to prompt accelerator use and grow the industry from there. If something like graphene can be used to achieve Terahertz speed processors, even very basic or large feature size ones, there are a lot of high value applications that are heavily limited by purely sequential calculation. Even if it's only a couple million transistors, some of those computations don't take much, they just absolutely need to be done one right after another and can take a very long time in a typical CPU.

I think there was some experiments involving a single molecule transistor, where (as the name says) where a single molecule reliably was able to work as a switch. I think the main problem is gonna be how do we putt a lot of these in a small space and how do we make it affordable. I think the future will be a combination of different technologys like nand flash based neural networks and conventional silicon with big simulation tasks being done by quantum computers in big data centers.

We will reach a point where instead of going smaller, we start building smarter transistors.
A bunch of binary transistors can do some work. But take a transistor and make it do more than 2 states?
That's where the big progress will come.
Neuron like computers that can dynamically adapt to different jobs, plus being able to remember information on the Neuron itself.

@@jakobmax3299 two question:
1. what was the molecule
2. how big was the molecule
don't forget, he mentioned atom-sized sheets here

@@ghoulbuster1 quantum computers are similar to what you are describing

@@kuhluhOG I dont remember, but thats not even the point. Transirors as we know the have a size minimum, and at some point we have to make the choice between affordable chips and the most powerfull chips.

Optics looks good for data transport, not so much for compute. Density could be a real issue there.

Unlikely. I never see any research on it at the conferences I go to

Not necessarily. You put more insulator around the wires, you get less tunneling. Lower voltage, less tunneling. Lower temperature, less tunneling. Etc.

@@Anenome5 I was talking about channel width, not insulation around wires. OTOH yes, one can also try to improve channel insulation, but that has already been done A LOT & I fear there won't be any space or way left to add sufficiently more insulation around channels to prevent decrease in channel off-resistance due to tunneling of charges/holes to such a point that field effect transistors can't be used as proper logic switches anymore so that engineers will have to embrace tunneling effect by using tunneling transistors & ditch field effect transistors entirely.

The process node is a name, not an actual dimension. :)

@@TechTechPotato yeah, I posted the question before I finished the video...
lol

You can plop down a nuclear reactor capable of delivering >1GW in basically any region so I don‘t really see that being a problem.
Also looking at the news, the US might have larger production capacity but their grid seems to be really really old and mismanaged with all the outages in Texas or fires in California.
And obviously if Taiwan ever manages to somehow burry the hatchet with China for good, they could realize something like the Asian super grid and build grid interconnects.

Check out Sam Zeloof. He's doing that sort of thing

@@TechTechPotato I have been tracking his progress for a while now. I was talking more about companies creating machines and the such.

I think that's what he meant when he said photolithography won't progress past euv in his lifetime (if ever)

TSMC has started researching alternative materials. I'm guessing this will materialize as new doping materials first and some R&D into manufacturing these alternative wafers, doping materials to create a band gap if needed, how to do lithography, and characteristics.
We've as a whole been researching alternatives for a while now. The hard part is finding one that is a decent semiconductor, or how to make something that's not a semiconductor actually be one with good characteristics.

@@Jaker788 Graphene sounds promising, kinda wonder if carbon could be added to silicon... if they could even slightly improve it's conductivity heat would drop massively.

@@glenwaldrop8166 The main problem is how to turn a superconductor into a semiconductor. They haven't found a good doping material yet for graphene

You need to turn off your transistor. Carbon is very good turning on but bad when turning off. That is the problem. If what you want is just a good conductor then use copper.

@@kazedcat You're ignoring half of my comment.
The switching voltage needs to be lower, hence adding a conductive material to the silicon.

Or, check it at wikipedia that node names are NAMES, not distances.

@@TechTechPotato That's clear but you can count atoms right now and thats the natural border to quantum weirdness !

Look at how large a fab is - and imagine the energy it needs to run. Now look at the price to build one fab on Earth.
Doesn't seem possible to build one in space with current technology besides the cost - light source needs gravity for EUV for example.
In space you also have more radiation which creates it's own problems.

Light based computing could benefit from space manufacturing because cristals grown in space have less defects.

@@JL-pc2eh Thanks for your insight. I didn't mean to build a whole fab, just enough to build parts of a cpu which could benefit from the unique conditions. Having enough power in space is no problem. There are sun-synchronous orbits able to generate electricity 24/7 at a higher power density then anywhere on earth. The dangerous radiation from the sun is directional and can be blocked by shielding. I'm not sure if you need shielding from other directions.

Unfortunately there are tons of steps for a chip that take months to get through. An entire chip fab is a very long assembly line/pipeline that must be passed from start to finish to get 1 finished wafer. When the power goes out due to a natural disaster, the whole pipeline and months of production are lost, and it's happened before.

@@Jaker788 I had an internship at a small III-V fab right before I started grad school and about halfway through the summer, there was a power outage in the fab. Boy the engineers were not happy - plenty of ruined lots! It was mostly discrete devices on larger process sizes, but it certainly cost a ton I'm sure.

Most foundry events are no photos, no video, no audio, aside from like the first 10 minutes. They go through slides at a rate of about 6 per minute and trying to write anything down. It's mostly show and tell for C-level customers and investors.

@@TechTechPotato Thank you

EUV used to be called Soft X-Ray in the 80s.

Sorry, had to delete the EUV lithography part, CZcams kept butchering my edit. LOL Welp. And yep, X-ray spectrum is honestly not as strongly defined though. X-ray and EUV lithography is challenging, especially, unfortunately with Tin sources having efficiency problems. Making very short wavelength light is no easy task.

Still, kinda looking forward to the Silicon-free transistor future as the Dark Silicon is kinda a problem, especially with leakages of Silicon transistors.

We tried to top and tail, but AMD insisted we had our own rooms.

@@TechTechPotato brilliant

I wouldn't be so down with Apple, they are bulk buying and paying up front which helpings funds TSMC's ongoing development. They are an important anchor tenant.

The low power mode doesn't like low power!

@@TechTechPotato Check out the G14 subreddit. u/ispeakuwunese has a guide post about getting battery life back and what he thinks they changed that broke efficiency.

It was my machine growing up. I'd write the BASIC programs out from the C64 magazines I'd get every month. Bubble Bobble on tape took 7 minutes to load.