I am one of the software engineers that developed the software for it. I visited ASML EUV factory/cleanroom in Veldhoven a few months ago, there were EXE machines fully built and some other big modules being tested. It is amazing, you keep staring at it and each time you find something different about it. Making 10 nm features in high-volume is allien tech, it is almost half smaller than the current best high-volume process. In general, making features 50% smaller would reflect on 4x speed/performance or more logic, but because it is NA bigger only in one direction, the gain is limited to 2x. For Hyper-NA I think they are going for 4x gain.

Many of my university friends work at Zeiss now building these EUV optics :) And we put them to use 😋

When I applied for my graduation work (MSc, Eindhoven University of Technology), the assignment was to work on this machine. And this was still 1999... 25 years ago...

350mil is bloody cheap for a industrial machine this sophisticated.

The things humans can make is kind of wild

You must have felt like a kid in the best candy store in the history of this planet.

I was happy that KZbin recommended me this video. :) Like another commenter, I'm also a software engineer, but working farther away from the actual ASML machine, specifically developing a software platform for executing adjustment processes on the High NA EUV projection optics boxes. It's quite exciting to work on something that even just supports the manufacturing of these cutting edge machines. We had a tour at the Zeiss clean room, seeing both the older POBs and a new High NA EUV one, and this latter POB in itself is already gargantuan. It was an amazing experience. :)

ASML have shipped Twinscan EXE:5000, this is great news. Thanks for keeping us in the (k)now

Ian is the champion of breaking down complex topics so even dorks like me can understand them.

The math, chemistry, physics, engineering and technology in these things is off the chart crazy.

You missed some of the best bits, after vaporising the tin droplets you then need to stop the tin vapour from coating your $1M lenses...this was a very hard problem to solve!

In my previous job, I help spec a desktop for one of these machines at a smaller scale. The machine was 2.5million and I was told go crazy with the cores. That one definitely is extremely HUGE

11:10 I wish I could buy a 250nm machine from 1980s for home use.

The Sub-fabs are just like stacked chips which is pretty cool lol, great video Ian.

Excellent purchase from Entel. This machine is incredible and Intel's progress forced TSM and Samdung to also place orders with ASML so as not to be left behind.

If you get any invites to more Fabs, (don't care how new or old) go on ALL of those Fab tours. Just keep traveling and visiting. This is where the rubber meets the road, semiconductor fabrication.

Now working for ASML. The equipment is very precise. Just the LASER for it is huge and has some serious IP in it's R&D.

I’m just a typical application development software engineer, I don’t have anything to do with this stuff, but i love learning about it

What did it taste like? They let you take a bite right?

Thanks for pronouncing Oregon correctly!

The inventor of lithography was Alois Senefelder 1794-1798. His invention is continuously perfected by ASLM and there is no end in sight.

It honestly both baffles me and restores my faith in humanity when I realize how much cooperation is needed to create and maintain something of this magnitude.

I'd love if you could bring us a tour of an OLED fab.

Amazing. Best of luck to their facilities.

Incredible how this technology is enabled by the top expertise from all over the world. The sector is so vast and so complex that it is unthinkable that one single country could manage all different aspects of high-tech semiconductor technology. Thank you Techtechpotato for producing this excellent video. Greetings from the UK, Anthony

that's so cool to catch a glimpse into a fab and actually see the latest asml euv fab machine.

Wow you have an amazing curiosity on all of these stuffs at such a young age. I was video gaming at your age without carrying about any of these hardware stuffs.

I love how in all these ASML videos there’s always someone who says they worked on something.

It will more than pay for itself

It really is mind blowing just how small these parameters are.

Impressive archivement both ASML and Intel for trying to push the boarders of modern lithography even further.

Its a miracle that something doesn't break at least once a day on that machine!

Imagine the truck driver looking at his cargo sheet and seeing the cargo value when transporting these machines 😳

3:08 “Standard normal sized people” had me 💀

A good size comparison would be to a train locomotive. Basically, those things are trains, just they make microchips instead of hauling goods and people.

lol I am the guy that yelled at you guys for one of your hoods being inside out! 😂

And they made, shipped, installed and run everything with solar panels. It's amazing they can do all this with net zero.

Can’t imagine the PMs on this thing

The money numbers are definitely headed in the direction of pentagon sized money numbers

You are really great. while you describe your visits to foundries, it feels like being there...

so at what point does it stop being ultraviolet and start being xrays?

It's really exciting to see Intel not only being the first to adopt High-NA EUV, but to have ordered the majority of machines ASML is making. Pat Gelsinger really seems like the right person to lead Intel into the future, as he understands that a leading edge fab needs to lead, as then their own chips end up great and competition will want to pay them for fab capacity, so Intel wins all around.

I don't want to imagine how complex these machines are

Flown to Seattle? I'd love to know why they couldn't fly it into PDX and just drive it the 10 miles to the fab from the airport. Seems kinda weird.

im laughing, i thought it was the trailer for dune 3, nice video, thank you!

The fact that the first thing that came to mind from that blurred background was High NA says something ig

I wouldn't be surprised if the vast majority of exposures on modern CPUs are still done with DUV

i used to work in f11, f12 and f22. i worked with D2 people in oregon. crazy that they're a month behinds asml. very smart of them to get their engineer's feet wet as clearly they got out of shape re: euv in general. decisions like that tended to bear fruit. we would literally do the same thing downstream for the high vol mfg sites training from the d2 folks as they did development.

Would be amusing if the tin droplet feed worked like a shot tower.

Worked on semiconductor equipment in fabs for 20 year. Loved it

I have some questions that I hope someone can answer for me. 1. Why does it require two passes with regular EUV? Is it because the light source is more diluted and can't do the job in one go? Or more like its a bit blurry? 2. From my memory of chemistry at university, 8nm should equate to about 40 pr 50 atoms. How on earth do you prevent or control all kinds of weirdness that result from electron tunneling? 3. Are we basically at the fundamental limit of how small we can go? If so is it just how well the architecture can be improved, and how much can AI improve it, or will it become a case of stacking layers on top of layers, potentially with microstructures that allow more efficient cooling?

TBH I have never doubted the competence of Intel brilliant engineers. I just hope the incompetent management didn't mismanage for too long and it's too late to make the fab business to turn around even though how amazing the engineering team are. We wouldn't want either TSMC or Intel become monopoly player after all.

I worked in that building, in the basement. That's where the pumps are located.

I do not understand how people can make so many fascinating things.

I thought the background on 0:52 was a bandaid on a thumb 💀

love it when a tech has a chair ,

Out of curiosity, how does the licensing work for those pictures taken by CBS? Like are they just released into the public domain or did each journalist/org on the tour get some kind of license? What kind?

the burka was so ahead of its time

If you fractor in the sells of chips, this is ACTUALLY one of the most advanced and expensive piece of equipment

hell yeah, this was cool as heck and super informative, thank you for this quality content.

I think it's safe to say that the next High-NA machine isn't going to China, unless you're Elon Musk and consider Taiwan as part of China. I think I had already read that ASML is going to work closely with Intel to ensure this gets up and running properly so we can assume there's other money involved. And Intel REALLY needs this because they mucked up EUV. And for those that don't understand this, Intel is making "Intel 7" with DUV lithography. They're making Intel 4 with EUV, but as of yet Intel 4 isn't making anything for desktop. I don't know the answer why. They had a LOT of issues getting to Intel 7 using DUV but that should have been expected since that "7" node is not what DUV lithography was made for. EUV lithography was made for that type of transistor density which is what TSMC does and why TSMC has pulled away from other companies. So, I expect that Intel wants to basically jump past EUV and get to High-NA EUV and put out Intel 3 and 20A ASAP to get back on the level of TSMC. Or, if this video is correct then have ASML help Intel with their EUV lithography so they can put out Intel 3 within the next couple years and I still think they want to get to High-NA for 20A regardless of what they say or their roadmap shows. Intel has had to do a LOT of edits to their roadmaps.

Mostly ancient Minoan to me, but if it results in powerful graphics that can run on AAA batteries then money well spent.

I know this is off topic, but any indication that Tenstorrent is going to go public?

This video just blew my mind, earned my sub

Its amazing to me that a machine that big is needed to make a small chip

Of course Dr. Ian has big chip energy. You can see it in broad day light.

Great video for the most advanced chip maker technology, also like to see the comments from all of you folks 👍🏻👍🏻

Numbers are bit inaccurate on the laser itself - there is 4 Resonators that step up the 2 smaller lasers ( baby lasers!) bringing a low power then an additional smaller amplifier to around ~150 watts all the way to an Average output power of ~30kW. The Pulse for the flattening is lower powered - but the Pulse that creates the EUV can be around 20MW per pulse! (think, we are averaging across 50 khz) but still - incredibly powerful - one of the resonators can cut through 2 inches of steel with ease - and CYMER/ASML/TRUMPF said... lets put 4 of them together! Look up TRUMPF EUV for a better understanding of the laser itself!

Must be our Dutch pride ASML

Some 25ish years ago I got to tour a DuPont fab

This EUV chip manufacturing technology is probably the peak of cumalitive human technology? If there printing 10nm lines how come people are releasing 3nm and 5nm & 7nm in marketing theory, chip structures? is that in a different orthoganol direction … ie vertical to the wafer layer itself?

you gave a informative discription of wafer fabbing

love these kind of videos i think this device is human kind most advanced piece of tooling we build so far amazing to see it in perspective on how large it is, and as you mention this is not the full device i wonder if you could snap some images on the floor bellow.

That's all very well, but does it make good gravy?

150 tons is actually quite light for something that big

Thank You For Your Presentation!

that thumbnail caption, hahaha :D

Had assumed this was Intel's own design.

Always enjoy the fab visits and I'm really hoping you'll get a chance to hit up Intel's packaging facility in New Mexico.

Amazing! I couldn't understand a single word in this video but amazing ❤

I wonder what's the current line width in R&D? A nice plot would be cpk vs line width. or a results from a field exposure matrix.

What happens to the vaporised tin droplets? I would assume they would cause a build-up of matter on surrounding surfaces.

I drive by this on my way to work every day but I never knew what was inside

Silicon photonics is the future of computing. Glass data storage is the future of physical media. MEMS technology is the future of sound reproduction. Combining all three will advance us in ways we can scarcely imagine. Borophene and graphene both present significant logistical hurdles, but silicon is both sufficient and plentiful. Microsoft's “Project Silica” has developed quartz glass discs which can store up to 500 terabytes and can last for billions of years, making it ideal for archival purposes. It also has massive commercial potential, allowing us to enjoy uncompressed media.

DEI had no part in the creation of this machine, only the merits of brilliant individuals

I'm the one that actually gave ASML the idea to build this

Awww.... I could have given you the tour!

What is the connection between ASML 8nm lines and the process for CPUs declared by Intel/tsm?

The old 8 inch fabs were actually cleaner than the current 12 inch ones. 12 inch had the product protected in the FOUPs whereas 8 inch the wafers were brought around in hand held and hand loaded lot boxes & cassettes.

TSMC and probably SMIC will likely do it again if this final wunderwaffe of lithography doesn't, for the love of god; give back leading edge to Intel.

I have read that Intel's newest machine is the prototype of what they are going to get. To test out this tech. So the production machine is still coming.

6 lasers coming together... Sounds like the Death Star...

I didn't even watch this but whoever the guy in the thumbnail is, he gets an instant penalty for not having his nose tucked into his cleanroom suit. How did this blatant demonstration of employee failure end up featured on the poster??

ASML is the most powerful company in the world. This company makes me proud to be Dutch.

3D printer tech needs to be ramped up to the level of these machines. so much so, that these machines are something that can be manufactured via 3D printing.

Astonishing.

Great Intel agitprop... Should keep the stock over $30.00 for a few weeks...

Not sure I follow your efficiency stuff @6:20 when you start with kWatts (power) and end with milliJoules/cm^2 (fluence). Units don't match and there is that 60 kHz pulse rate in there as well.

Correction on the title , Intel buy $350 million chip making machine from ASML. Now i seems like they made it. ASML HQ isn't even in the states although admitted it does contain american patented parts and Intel does own ASML stock like TSMC and samsung.

Proud to be Dutch. 🇳🇱