I tried to make a camera sensor

🚨 *Addendum* 🚨
- I can't electronic my way out of a breadboard, so apologies for any basic EE mistakes! I just want to build the devices, not actually use them in circuits or whatever 😇
- In the PN/MSM animation, the electron/hole move in the wrong direction. Oops! Just pretend I know how to animate things correctly 😅
- Copper (I) == Cu2O and Copper (II) == CuO: This is very confusing! But it relates to the charge of the copper cation. Oxygen has a -2 charge, and in Cu2O there are two coppers per oxygen so they each carry a +1 charge hence (I) in the formula. CuO only has one copper per oxygen, so it carries a +2 charge and (II) in the formula. Very confusing to read out loud though 🫠

The average selling price of a CMOS Image Sensor is currently just above $3/sensor. The semiconductor industry is insane.

It's insane that there are *multiple* people on youtube doing DIY semiconductor fabrication. Not only that, but you're getting sponsors from industry instrument manufacturers, instead of mobile games and VPN providers

"DIY" and "semiconductor" are not words I normally see in the same sentence. tbh it is pretty awesome.

I just love the fact that a high tech corporation created a bleeding edge microscopy technology and said to themselves: "We need an influencer to promote this product." Whaddaya know there actually is such a guy, and I follow him on YT. The internet is beautiful sometimes.

"I hope it was interesting...", really? This is just mindblowing... yet again

At an (amateur) astrophotography conference, the keynote talk was given by a "professional" astronomer (e.g., he got paid to do it, rather than spending his own money) who described a sensor and camera his research group built. It could do single photon detection AND also measure the wavelength of each photon's detection event. There is some solid state physics phenomenon whereby they would fabricate a feature on the chip they designed, such that when it interacted with a photon, it's effective capacitance changed by an amount proportional to the wavelength.
So they would fabricate an array of LC pairs, organized as pixels on the wafer. The intention was that each pixel had a different, unique resonant frequency. Then they would pump the device with a broadband noise spectrum and then look at the resulting spectrum with an SDR receiver. They would observe a spectrum with a bunch of notches in it, corresponding to the resonant frequency of each pixel. When a photon interacted with one of the pixels, the notch in the spectrum would shift according to the wavelength. How fast you could run the FFT in the SDR software gave you the time-tagging precision of the detection event.
He described the many iterations of fabricating his detector (with a 64x64 or maybe just 32x32 array). Some pixels would have the same resonant frequency as others, sort of aliasing them. Other pixels were, of course dead. Etc. I don't recall if the detector needed to be cryogenicly cooled in the camera body or not.. Many things were learned the hard way. I chatted with him after the fact and told him he had the most interesting job in the world, comprising: astrononmy, solid state physics, semiconduction fabrication, software defined radio and, of course, grant writing 🙂
At the end of all this, they did get to observe the pulsar in the Crab Nebula and time-tag those observations with simultaneous radio telescope observations to confirm the direction relationship which hadn't been done previously. What a long, long road to that result.
Thanks for your video, it was really quite amazing to see all these fabrication steps actually done right before your eyes. And it gives me just a hint of the "art" beyond the "techniques" that goes on in modern semiconductor fabs.

This is absolutely insane to be able to do this DIY outside of an industrial setting. I've never seen anything like this attempted, amazing!

Your hair cut speaks volumes about the complexity and frustration of this project :D

Once every few years someone drops a new diy semiconductor vid and its the my favorite thing

That interleaved pattern reminds me of experiments that I did as a kid back in the 60s with paper and a soft (#1) pencil. I got the idea for the interleaved pattern from seeing a CdS photocell. As graphite conducts electricity, I drew the pattern on paper, coloring it heavily to make it more conductive, then smudged the space between the 'fingers' with a cotton swab. Connected dad's ohmmeter across it and watched the resistance vary with light intensity. Graphite is photoconductive.

he's got that medieval blacksmith look locked down, give him a leather apron and a hammer

Your ability to go past the part where Copper II is Cu and Copper I is Cu2 without snark is one of the many ways you're better than me.

Can't believe how much technology has evolved. Like there are millions of similar stuff in your phone cameras right now and don't even get me started on processors

This honestly insane to me how you were able to just fab a working “Chip” essentially.
Im IC Layout Engineer working for a major Semiconductor Company and the amount of things you got correct in terms of the process (especially the double layer deposition for stepwise etching) while just studying a nature paper is honestly impressive.
Im guessing your problems with the misalignment at the end have something to do with your process, you need to do some test alignments and see how “offset” from the grid your Cupric Oxide Layer is from your aluminum layer. Then you can just design your “masks” around that offset. We usually have alignment marks for these sort of limitations in Manufacturing.
We mostly design Power Management IC’s in our Design Center, so I can’t say for sure if your MSM array will work, but Im hoping to see more like this soon. Great Job!

Its SOO cool to see topics I studied in university applyed in practice - learning just the theory and doing it all on paper made it seem so bland and boring. But every time I see someone actually DO the theory, I am just stunned and miss this part of my life ... thanks for bringing it back to me

Wow, you've come so far from your early videos of rebuilding a mill to this! I can't wait to see your 0.000016 mega pixel camera. On a completely different note, am I the only one who sees a Trojan Horse in the short circuit at 27:13 ? I guess it's a bit of a Rorschach test.

I know your lab is significantly better than a lot of home labs out there, but it still gives me hope that one day we'll have DIY electronics from scratch. I love the thought of just plonking down a box in the corner and sending it a file and a few hours later a new chip.

Absolutely incredible, even before demonstrating the sensor arrays, this is one of the most impressive single-person projects I've seen - that's a significant fraction of the technology required for a usable semiconductor process (and not even a huge node, 800nm is totally functional), just developed by one person! I can't wait to see where this goes :D
(Yes, I know about Sam Zeelof's ICs, but unlike his approach, this video includes making the semiconductor as well - basically a SOI process, but not silicon)

10:16 that fluid simulation must have taken a long time

In case you all wanted to know, here is a list of metal-to-oxide adhesion layers: Ti, Cr, Al, Ta, Mo, Nb, V, & Hf. I have used Ti, Cr, Ta, and Mo in my chips so far, for adhesion.

There was a thread on twitter where people in the industry were discussing how expensive oscilloscopes when turned on create unexpected voltage on the probes with some destroying the test object and how there are recall campaigns due to this issue..
Fascinating work as usual, mate!

DIY semiconductors are my favorite type of videos. Want to say that your attempt at a full device was a great satisfactory ending for this work, and I'm really looking forward to you finishing it

A+ work here! In high school I made circuit boards by using toner and etching with HCL, this is truly several steps up from that. One day I dream of having my own lab to be a mad scientist like you

Most interesting ad I've seen on youtube

I know I've watched dozens of videos over the years for how digital sensors work, but I swear to god this is the first video I've seen in my life that actually explains the scientific details in terms that ordinary people can understand ❤

This nano stuff is fascinating. Even though these scales are so tiny that they escape my comprehension, it's so fascinating to look at.
27:55 now I wanna see a collab with the SloMoGuys to see what the hell is happing there at 100k FPS.

I can't believe you're able to do DIY semiconductor fab, AND do it while making a great video. Incredible stuff as always dude!

I work at a major semiconductor fab on some cutting-edge lithography tooling. Intel High-NA team if you want to see the machines themselves. I love seeing semiconductor tech start to show up in the DIY space. I'm hoping we see somebody try to home-brew a 4004 in the near future.

This is the first video of yours I have watched/come across and I just want to commend the detail and patience in describing not just the processes and intent, but the tools in use, and dude... way to save 30 grand! You burned over that so quickly but seriously that alone was so impressive!

Man this is the video that I've wanted to see you make for a while now. Very cool stuff, can't wait to see the stuff you do next with diy image sensors!

Nice DIY photosensitive fuses. Now I can finally know if the lights were on when the fuse blew! 💡

Felt like a three minute video. It has genuinely been a while since I've been so immersed and attentive during a video, thank you.

At this point your videos are my favourite thing to watch. Incredible effort, and surely an entertaining outcome. Thanks for all that you're doing!

Very cool , i can't belive what you achived in basically a home lab . Can't wait for the next video

Seeing how much work it takes to make such a tiny sensor really makes me appreciate just how much work goes in to modern computers. It's remarkable that we can make the chips we do.

Really cool. Been really fascinated with how far copper semis can be taken since I saw keystones videos on a copper oxide solar panel.

Man this is the first sponsor spot I have ever been *invested* in. I learnt a bunch of stuff and that tech is AMAZING. Kudos to them for being so open with how it all works and for sponsoring you to do this cool project. Only suggestion might be a little blurb on why this copper semiconductor photo sensor is special other than being fabricatable? Unless that is the prime attraction? I just saw "high performance" in the title of the paper was all.

Every time I see one of your videos I'm more and more impressed with your knowledge and skill with this kind of thing!

Absolutely amazing from one end to the other. The AFM-FTIR thing is super cool! I made a simple AFM in grad school, back in the early days, so interesting to see how many different directions that idea has gone.

this was so mind-boggling, it took me 3 sessions to go through the video. Amazing stuff there, sir

As usual this channel is absolutely insane. Props yto your progress man

Very nice, good job. The alignment crosses at the end had me in tears.

Great video. And this is only the first stage. After that there is all the electronics to actually transfer the pixels, manage exposure time, HDR, serial communication with external IC, etc. Makes you realize the complexity of these devices that we take for granted.

This video was uploaded 5 hours ago. To think about the precious time, I have wasted doing something else besides watching your video... Thank you for uploading something just in time to make this day an enjoyable one, after spending countless hours on a task that could have easily been automated. You literally saved my day!

1:10 This may be a stupid question, but how can the semiconductor be naturally p-type? What is acting as an acceptor in undoped CuO?
3:40 If the copper - after solidstate dewetting - follows the underlying Silicon crystal structure, then what happened to your Oxide layer? 3:55 looks particularly interesting. What as the big blobs and why are they not merged with the little blobs?
A thicker SiO2 layer may have helped as well.
And last but not least, label your KLayout layers god damnit! So we can be even more hyped for the next project!
KLayout also has a macro interface. If you want to process variations of the same layout (e.g. with different spacing) you (or I) can easily write you some code to do that. Hit me up it that would help.

Oh man... this makes me hopeful for more home fabrication tools in the future. Really amazing work you've done here!

These videos really do a great job of inspiring me. These really help quantize intimidating topics like "DIY semiconductors". Amazing content, keep it up!

Dude this work was insane, very good! Amazing attention to detail

This is AWESOME!!! 20/10, thanks for the great video! ALSO, thanks for introducing me to the PiFM technique! that is AMAZING!

Always a pleasure when this channel has new content.

This video is awesome. Form the lighting to the rendered diagrams. And the subject is super cool

You, Sir, just earned a subscriber! Doing this as "a random youtuber" is NUTS! I thought "Breaking Taps" would be a machinist or automotive channel, but looking through your back catalogue tells a very different story. Can't wait for more!

wow - I can barely fathom most of the science in this, but I need to see where this project goes. Subscribed, and godspeed!

I love your diy probe station mover. Reminds me of grad school where we did a similar hack to move about entire microscope using some ball bearing drawer slides and an x-y manipulator

As usual, absolutely amazing and lots of relatable moments 😅 keep it up!

Very cool! You're rapidly approaching Applied Science level of projects.

this is so cool man, I really enjoy that there's people doing this stuff

those renders are so cool! amazing work

Unreal ! I can't get enough of this stuff please keep up the great work but don't lose you sanity !.....cheers.

I've been trying to explain how silicon manufacturing works to my dad and this and your MEMS video will help him understand some of it, thanks. If you ever find the time or need to make a short'ish (10-20 minutes) video about it, please do so. You're explanations and graphics make it much easier to understand.

Such great content and so nicely produced. I was not at all interested before I started watching, and now I am fascinated and intrigued

This is astounding. Thank you so much for sharing! ❤

Great content as always, but the real gem was introducing me to PhysicsInFlight. Finally understanding the underlying principles makes watching videos like yours so much more enjoyable.

Absolutely stunning graphics and visuals. Great video!!

Possible food for thought : when I get discouraged I try to remember that it is the act of attempting projects and trying to figure things out that I actually enjoy more than the completed project itself . Any way awesome video brother man can't wait to see what you come up with next.

Interesting. Love the timely paper reviews mixed in.

Your channel is amazing man, much respect.

In high school I took a printing a publishing course, and part of it was on screen printing. We used photo lithology to make the stencils. You would lay out the pattern in light sensitive paper, as a negative, and then shine laser on it for 20 minutes. After placing the cued light sensitive paper on the cloth screen, you could wash away with a forced water the non-protected areas and therefore create the stencil to screen print through.
I'm sure it's not the modern method for screen printing stencils, but it was cool to do by hand, and so many of those principles of lithology carry over.

Besides the amazing-ness of your experiments, that molecular-composition AFM is beyond next-level; I had no idea such things existed 🤯
What an insane device, I can’t imagine the R&D that

Im a Student in a German University of Applied Sciences and studing Elektrical Engineering and i had a course last semester about semiconductors. This is so amazing. Thanks allot

super cool! great work and I can imagine how much patience required to get this far. Lovely work on the animations too!

This is a really awsome project. I wish you all the success you need for this. :)

So cool! Hopefully one day we'll have a Breaking Taps video filmed on a Breaking Taps imagine sensor!

Very interesting!! You could update your furnace by putting a modern PID temperature controller on it. They support multiple different kinds of thermocouples, support hysteresis settings. Not sure about the internals of what controls the filament in your furnace but people wire in PID controllers to their espresso machines with great results and even some data logging functions. Keep these awesome videos coming! I learn so much from them.

Besides the amazing-ness of your own project, that molecular composition-sensing AFM is just beyond next-level! 🤯
What a crazy device, I can’t imagine the R&D and engineering it must have taken to turn it into a usable instrument. The whole thing is down to second-order effects; near-field behavior, detecting the photo-induced forces as changes in the resonant behavior of the probe tip, etc,etc. what I would have given for one of those back in my university semiconductor-related research days!

Nice work! Love the alignment mark pic 🤣. I feel your pain brother. This work is teaching many valuable lessons. The most important: Never bet against silicon.

Genuinely a brilliant, very interesting video. Thank you for the very hard work.

Applied physics are the coolest. Thank you for sharing this increadible project with us and your time spend into producing this video.

I do wish more lab equipment manufacturers dld more things like this -- this is absolutely the right audience for those machines.

Please continue ! Cannot wait to see more of this

Wow thank you. Learned a ton and appreciate your approach to setbacks.

I am amazed at the quality and effort behind the video, pure eye candy animations and the sponsor is actually participating in the project with their amazing technology. Since it's so sensitive, does it run in a vacuum or just clean air? The box doesn't look like a vacuum chamber.

just WOW!! mindblowing 🤩 optoelectronics is just such a marvellous matter and you did it at "home". Kudos to you

The age of home lithography is here and I am all here for it

Such a cool project!
Love it!

I held my breathing to the last second of the video sitting on the edge of the chair. Man put live stream cameras around. I'll watch them 24x7.

Wow! Nice job! Keep up the good work.

Man... This is what I like seeing! I do this stuff too for my videos (on another channel), and I have to put it all away before my kids get up in the morning.

Absolutely incredible! And gorgeous footage & graphics

its incredible to me that someone figured all this out

Awesome stuff, thank you!

It would be great to have a light wavelength sensor that could be used to monitor a variable LED output source. Accurate LED wavelength calibration could help identify variations in color blindness.
It also could be used to measure the color phase shift with those suffering from macula degeneration.
(green LED light phase shifted to blue inside the eye thru the macula)

Absolutely amazing work! I am speechless.

FYI, you can somewhat better points on the probe needles if you translate the points up and down in the NaOH; that results in a rounded, convex tip vs. the typical triangular shape. We used to wind up curling the points when probing because there's a bending moment from the geometry of probing. The rounded tips would last 10x longer, because there's a larger cross-section.
That's something I learned during an internship at a semiconductor lab during college, many, many, eons ago.

Wow, those lines of copper at 3:44 are super cool! I feel like there might be some unexplored material science applications there.

Very neat seeing what failures look like at the end!

I love your channel, your work is incredible

Your videos are very unique and you're highly skilled, thank you for such interesting content

There were two papers I found a while back that cover creating transistors w/ cupric oxide. The bandgap is narrower w/ CuO which enabled them to make transistors that are lower power and able to switch faster than silicon. If we could even get CuO integrated circuits at the semiconductor fab scales we had a decade or two ago, we'd likely still be ahead of the Moore's Law curve because we could overclock those suckers way harder! We could make CPUs larger to have the number of cores we're accustomed to today, and run them on less power.