How an ASML Lithography Machine Moves a Wafer

Holding ~1 nm alignment tolerance over meter-scale distances is hard enough; holding that tolerance dynamically while the waver and mask are moving at a relative speed of several meters per sec is insane. In the time it takes the light to get from the mask to the wafer, the wafer will have moved something like 5 nm. So somewhere in those billion+ lines of code controlling the system there is a correction for the finite speed of light.

kenjohnson

You realize how precise this operation is when he says "... refractive index of the air, which changed as the stage moved around, it threw off things by as much as ONE NANOmeter, which was UNACCEPTABLE..." that is really crazy!

yibosun

It always blows my mind how complex these machines are, how many technologies and innovations that has devoloped over decades to reach this point. Probably the most complex thing humans have ever constructed.

Aurora-nvbr

I work in a cleanroom assembling these machines for ASML. We hold tolerances in microns and this video gives a good explanation of just why we do that lol

mattk

The technology behind this is (to say at least) insane. My dad worked at RIZ semiconductors in Yugoslavia, they made transistors and ICs. He regularly talks about his days working there and how interesting and good it was. He was very sad when company shut down before the war and he never recovered from it. I can imagine how happy he would be if they had something like this in factory.

themrworf

The hydraulic backstory of early ASML is really fascinating. Little historical lessons like the chip manufactures rejecting ASML equipment make for powerful stories to understand and explain decisions you'll need to make in the future. Great video!

DemPilafian

Fun fact: I grew up in the city of Eindhoven and the Philips Natlab lays in the cities district called “Strijp” when Philips moved out of Eindhoven with all their manufacturing facilities this part of town became like a ghost town. The municipality of Eindhoven invested heavily in the district for the past 10 years or so and it now houses many restaurants, cafes and foodhalls. The old Philips factories have been converted into apartments, offices spaces, start-ups and the district really became a new hotspot for the city.

DJThinICEofficial

They do all this so I can watch my NETFLIX. Thanks for your efforts ASML.

normalizedaudio

I worked on these tools for 15-16 years at various sites. From. 2500s, 5500s all the way to NXTs. Left ASML in 2018 to live a more peaceful life in the Philippines. Working under pressure to deadlines, to customers watching your every move, I have not regretted my decision. I am out of the rat race. As they say, money isn’t everything

hrldoliente

I worked with a former ASML mechanical engineer for a while. He was of the opinion that the ASML stage is a masterpiece that has held up for decades and generations of machines, and he obsessed over specifications I have never heard of. Fantastic stuff

tykjpelk

So fun to see the ASML videos. It is interesting to see what has and has not come passed the walls of our company. As someone that works in their learning department these videos are great inspiration. Keep it up!

McKon.

I thought it was funny that the air bearings involve the wafers “floating” on a granite slab. All these wicked complicated polymers and materials and chemicals, and they use a rock to glide the wafers around

Mike-zlzs

Fifteen kilograms. For an easy point of reference, that's the same weight as twenty-six Cornish piebald hissing marmots.

AppliedCryogenics

The thing that really makes my head 🤯is that the wafer and reticle are in motion during the exposure. They move opposite directions with a tiny slit between them such that only a narrow line of the image is projected onto the wafer at a time. The relative motion of the two needs to match exactly so the reticle image lines up with the correct part of the wafer.

So that crazy 1nm overlay spec that you were probably thinking is a "line up and hold it still within 1nm" is actually "drive the wafer and reticle in opposite directions while accelerating at 20Gs and do not allow the speed of either the reticle or wafer to deviate by more than 1nm from it's predicted x or y location at any point along the path."

sooocheesy

Fantastic video containing a lot of details I wasn't really aware of. Thanks for making this!

HuygensOptics

I love your litho videos bro I’ve seen everyone at least 5 times. Your videos are the only ones I have found that go into great detail about every process and very easy to understand. This semiconductor field just fascinating and boggles my mind

HostilityXBL

YES! more videos on how the ASML machines actually function please!

pauldziejman

I've designed and built quite a few motion systems for this industry. This is a great summary, thank you! I love your videos, first time commenting, just had to say it!

theianmce

I found this so interesting! Moving 15kg with nanometer precision in 6 degrees of freedom with about 20g of acceleration is just extremely impressive!
Not to mention training all the sharks for the laser metrology job.

DiffractionLimited

Correction on your throughput statement at 10:06. 125 wafers per hour is about two wafers per minute, not one wafer every two minutes. This isn't the only time you make this error in this video.

davidproctor