As a lithographer, I'm always amazed by how chip designers optimize and design their chips so they can actually be manufactured on our machines, given all the conditions that we give you guys. Mad respect!

​@@DrBlokmeister I'd be very eager to learn if both of you listed some of the more interesting constraints. Perhaps the chip designed and the lithographer might even have different takes about which constraints are the trickiest. I have some vague ideas of the constraints, but am neither a chip designer nor a lithographer, so my understanding is a bit abstract and still rather hand-waived. For example, I recall some of the constraints deriving from the diffraction pattern on the mask such that if certain desired patterns are placed to near to each other, there's no way to construct a diffraction mask that generates that pattern due to various interference effects. Corners and ends of lines are particularly tricky. I recall that many chips now use multiple patterns per layer in oder to work around these imaging constraints by putting part of the pattern one mask and part on a second mask.

@@ddopson The constraints are I think more subtle. You are definitely correct. But in the end it's all about achieving a level of contrast and the correct feature width (CD) that is acceptable for the rest of the fabrication process. Depending on the topology of the structures, you need a certain depth of focus and might need to tune the machine to reach the desired values. What you're saying is also not wrong. I think in the end our constraints are combined with all the other constraints in the manufacturing process, determined by the resist, material properties, etching, etcetera. Those final constraints are then communicated to the chip designers. At least, that's how I thought the process goes. If a chip designer tells you differently, believe that person!

​@@ddopsonFrom what I understand, a lot of these details are ironed out by the foundry through their DRC (Design rule check) ruledeck. These have rules at their most basic do things like 'don't put lines closer than x nm to each other' or 'no line shorter than y nm', but quickly starts doing very complicated things like 'minimum line spacing is x nm unless you have more than y lines next to each other in parallel of the same width then you can decrease the line spacing to z nm except in the case where you need to contact the lines with a via in which case it changes again' blah blah blah, to the point that these rule decks are literally hundreds of pages (I think the one for the technology I worked in most recently is over 400 pages). This is where a lot of the crazy stuff really is - there are rules that will allow you to only place lines on the finest structures in a certain pattern, with certain repetitiveness and on a grid, to make use of diffraction patters (or at least that is how I understand it - Sander might be able to correct me here). Another example is that you might start using multiple patterning, where one metal layer is split up into multiple masks and soon to make more complex shapes possible. The chipdesigners who really come close into contact with this are the people who design the standard cells---the basic logic gates---which really need to make as optimal use of all these tricks and features as possible, since they drive area of chips. In what I do (millimeter-wave chip design), the things that determine cost and area are not the transistors, but big passives like inductors and capacitors, and so we mostly look at performance of the transistor and not the area.

@@JorenVaes Very cool insights and context that you provide! All these rules you mention in the beginning make complete sense from an imaging point of view. Of course if all you want to do is place lines and spaces together, you can squeeze them in to the limits of your optics system. But as soon as you need something else, then that's gonna come at a cost. The more repetitive your structure, the easier it is to optimize for. If you want multiple structures at the same time, you have to optimize for all at the same time, and this means that all feature will perform worse than they could if you'd print them separately. Also if you put things on a fixed grid, then your diffraction pattern will be discrete, as the Fourier transform of a grid is also a grid. This makes it easier to optimize the illumination settings (incidence angle of light). As soon as you want to place one feature off-grid, it will likely underperform and maybe not print well.

Is that a computation that parallelizes well?😂

⁠@@salmiakki5638The light simulation step part is, iirc. But the steps before it that apply design rules so that it works well, are totally dependent on CPUs only as they’re too complicated for GPUs (way too much branching logic)

Itschain- cell-hainelopment process. Chip calculates mask for even more powerfull chips ... Skynet is coming ... AI will prevail

so do you use any spherical optics at all? and in terms of tolerance, what are we talking about? ion polishing everywhere?

@@diegogmx2000 I don't know, and if I did, I'm not allowed to say. Zeiss makes the lenses, they are the lens designers and fabricators, so lens design is technically not an ASML thing. We only use the lens. Although in reality the difference more subtle.

@@DrBlokmeister damn, im still surprised how compartimentalized these things are, good ways to stifle innovation to keep monopolies

@@diegogmx2000 I think it's also a result of the complexity of these machines. I don't know a lot about the complexity of the wafer/reticle handling robots, I have a limited time and brain capacity. The machine is too complex to understand completely. I'm not an expert here, but I think this is also why ASML outsources for example this lens design and manufacture to the companies that are the experts in this field. We know roughly what kind of a lens we need, and let the experts decide how to make that lens. That way we get the best lens we can and can focus on our expertise.

Unfortunately, the field in the animations is quite a bit more limited.😁

That's so true! All these fields are similar. The lens is simply a band pass filter with size of NA/lambda (in frequency space). By changing the incidence angle of the light onto the mask, you can change the position of the filter from minus half the lens size to plus half the lens size. As the diffraction pattern is simply a fourier transform of the electric field at the mask, it is easy to calculate the final image! You just have to iFFT(FFT(mask)*lens) and BAM! You're an imaging engineer!

​@@DrBlokmeister🤯 it really is fourier sequences all the way down. Wheels within wheels...

Also didn’t think my basic understanding of “beamforming ” would apply, but shouldn’t be surprised that an array of light sources would not behave in a similar manner haha

​@@DrBlokmeister Interesting! So I guess I can think of the lenses role in imaging as a convolution, since multiplication in k space is a convolution in r space. I've never thought about optical imaging in this way, only XRay and MRI imaging (medical physicist by training), but I guess it makes sense that it's similar. If the lense is a rectangular band pass filter in k space, where would I find the corresponding sinc in real space?

@@chalkchalkson5639 I think you're right here. The lens has a point spread function and the final image is a convolution of the point spread function and the mask. I think it's a bit more complex in the case of off-axis illumination. This sinc function is the point spread function I mentioned. It's the response of the lens when you try to image an infinitely small dot. Since for an infinitely small dot, the diffraction pattern is infinitely wide, the entire lens is filled with light, the intensity being 1 over the entire lens. Therefore the image will be a fourier transform of this square.

I have put Asianometry (read Chinaometry) on ignore.

​@@3pan1Why? That channel provides useful info and makes some historical videos too.

@@ErnestasMage If you are able to read between the lines; something you are apparently not capable of, you would have intuitively felt and understood that channel is a quasi universal chinese propaganda instrument.

@@3pan1 Apparently just because the creator lives in Taiwan, he produces propaganda? I have watched numerous videos of his and found no inclination to believe that he supports that stuff, maybe it's just you, who only watched a little bit of his content, formed an inaccurate opinion?

@@3pan1 Watched alot of his video and i disagree, just because you cover a stories or a sector's progress doesnt mean he is doing propaganda. His video that tae place in China in the last 40 videos is 3(exclude those from Taiwan). Stop cherry picking to fit your delusional assumption, it only prove that you are a fool in disguise.

It is insane! When you work on the nanometer or picometer scale, suddenly everything matters! I never hear about the challenges that other companies have, so it's interesting to hear these things!

I work in metrology team at ASML. Indeed, being able to measue incredibly small features at high enough throughput is incredibly challenging.

For EUV in your garage, probably you can be extremely happy with a k1 of 10000. :D

Awesome! What's your light source ?

@@Hippida a kid rubbing two sticks together really fast?

And of course it's got to be 3D printable so that all of us can make a copy and start a DIY wafer revolution ! 😂

Please send me (SBLS) a message and I'll arrange my famous lecture for your team if you're in VHV! By the way, mad props for you source guys and girls. You guys do impossible stuff. Building steppers is something we've been doing for decades, but shooting steel-cutting lasers at supersoakered microscopic tin droplets flying through vacuum at 300 km/h twice fifty thousand times a second is completely insane. The fact that there isn't a conspiracy theory around this is a miracle. Hats off to you!

Thanks, I guess the work on the EUV source also has its difficult aspects but these would be more in the field of lasers, plasma generation and timing. Anyway, glad you liked the video!

Absolutely love this channel and was delighted to see ASML come up as a topic. From the little I know about it, it looks like one of the most important and most under-appreciated companies on the planet. The EUV light source seems like one of the zaniest components in the whole mind-boggling machine. Piece of trivia which I'm sure you know -- the holder of the patent on the liquid-metal-jet method of generating EUV is Hans Hertz, great grand-nephew of Heinrich, and professor at the Swedish Royal Institude of Technology. He's from a long line of physicists and I've wondered if his liquid-metal-jet technique is in any way connected to the fact that his father, Carl Hellmuth Hertz, held the patent on inkjet printing technology.

@@ps200306Supposedly they are indeed very similar problems, yes! You need to control the volume very precisely, but also quickly, and produce a globule of the same shape consistently. I forget which one, but one of Asianometry’s videos mentioned this. For printers, MEMS is used. I wonder how it’s done for these machines! The working fluid is more difficult to work with, and its higher temperature, and continuous. Very difficult working parameters!

@@ps200306 I never heard of this. That is so cool!

Yes I saw. Nice high resolution. Did you modify the code in some way? I remember that in the past you had some trouble simulating high-frequencies.

@@HuygensOptics Not in any fundamental way. But I increased the resolution, so this may explain the difference.

​@@NilsBerglundI knew I recognized those animations. I love your videos!

@@andrewcornelio6179 Thanks! In this video, Jeroen used another software to create the animations, though.

Good idea. But let me first get a second life.😉

@@HuygensOptics In the meantime, how about an AMA, with ASML? :D

Somehow that nm precision is never that amazing when looking at micro electronics (everythings is small so in relative terms it is not as impressive). But when you look at large physical systems moving at high speeds and distances for us humans, I am always amazed that it still as precise as some of the smallest things we can make

Thanks! But even for us guys and girls, the stuff that we do is incredible. I focus only one tiny aspect, but when I speak to colleagues about other aspects, every single one comes with jaw-dropping things.

⁠​⁠@@DrBlokmeister I think you meant “jaw dropping,” not “draw dropping.” Otherwise it sort-of sounds like you are talking about peoples’ underwear falling down. While comical to imagine happening at ASML, I don’t think that was your intention.

@@WhatYouHaventSeen Ooops! 😅

Some people don't believe we landed on the moon. I've stood next to an EUV machine running procution at a foundry and sometimes I almost wonder if it is a hoax. The technology is so bizarre!

Is truly absolutely fascinating. But have in mind that ASML has workers, engineers and brilliant minds for all over the planet and also the main components and technology comes from several other countries and without them this technology and machines will be impossible. What this machines do and also the others thousand machines do to fabricated the logic and memory chips is absolutely the state of the art and are some kind of magic for an ordinary human being.

It is completely insane! We have subnanometer accuracy while moving at speeds per second that are almost nine orders of magnitude larger. Let that sink in!

@@DrBlokmeister So that's where the UFO tech ended up!

@@chrimony I'm officially not allowed to say this, but the aliens actually steal from us.

yeah. working there sucks

@@DrBlokmeister Your secret is safe with me.

Good luck, hope you get invited for an interview!

@@HuygensOptics Thank you. Fingers crossed!

Good luck! If you get hired and are interested, reach out to SBLS. We can geek out over lens designs and imaging!

@@DrBlokmeister Awesome. Would be fun. I'm currently building a drift scanning camera for astronomy (my other hobby) so your thoughts would be much appreciated!

@vincei4252, ASML is on hire freeze right now, don’t get discouraged if you don’t get the position at this moment.

isnt it already solved (coreless linear motors, superinvar/zerodur structure scale,close loop feedback, all in vacuum ?) just guessing, no idea how it is really implenented.

@@AABB-px8lc I mean, just stating close loop feedback like it something that is perfect, or a completed field is one way gloss over the entire field of controll, which is not solved and won't be for some time. (read this humorously and not as some attack)

This for sure. As great as this video is, I get a feeling so much was left out

For obvious reasons that's not going to happen 🤔😉

I even considered a career in the Space industry before I joined ASML. I still hope for the day that in an effort to completely eliminate vibrations, we have to launch our scanners into space! Best of both worlds!

What do you mean by the transform matrix?

That was indeed the cherry on top for me as well!

You are so right! Just an example. If the silicon wafer heats up by just a millikelvin, so a thousandth of a degree (2 thousandth in freedom units), it will expand by roughly 3 nanometers, completely destroying your chip.

Pre-patterning orientation check: masky end up, wafery end down! All systems norminal.

To my regret, this nerdy T-shirt is the only visible achievement of the Russians in ASML technology. Печально.

Same to you!

Tes it is :)

It definitely is! If I wasn't a lithographer, I would be a rocket scientist! A lot of things are interchangeable, such as the orientation check of a rocket or lens. Low NA end up, high NA end down. Low NA also makes for a more pointy end.

I'm always open for it!

I will likely do another visit in the future (if they will allow me). There was so much more to explore. But first, I have a few other interesting subjects I want to discuss, quite related actually.

Glad you enjoyed it! Huygens Optics made it into something beautiful.

@@DrBlokmeisterAlso looks like all of you generally just had a great time 😃

@@harriehausenman8623 haha very true. We spent the entire day geeking out.