*Addendum* - The "tactile buzzer" is just the battery. Brain fart, not sure where my mind was when writing that out. Whoops! 😅 - Some folks were curious how the middle gap between the layers is made. I don't know for sure, but it's likely that they used a sacrificial silicon dioxide* (SiO2 aka glass) layer in between the two "functional" layers. So the process flow would have been: pattern and etch bottom layer's array of holes, deposit a thick layer of SiO2, deposit and pattern subsequent polysilicon layers (doped or undoped), then finally etch out the SiO2 layer with HF or plasma. Then flip over and DRIE etch the big cavity from the backside. That is also likely why the dimples are dimple-shaped... they are just following the curve of the sacrificial layer that was filling the holes from the very first layer. *I suspect SiO2 because there was some EDS data (not shown in the video) which showed high concentrations of SiO2 right at the broken edge between the layers, where they meet at the "bulk" of the substrate. I think that's leftover from the sacrificial etch process.

Honestly I might be most impressed by the fact that you made a 3d model of the microphone for a mere couple seconds of footage!

The fact that this sort of tech is $10 for a whole system is literally marvelous. 30 years ago this would be actual magic.

"Buddy I can't hear ya, think you forgot your microphone in the electron microscope again"

Your video making skills are off the hook. I love the CGI of the microphone and all the beautiful imagery. Your hard work to make these videos is super appreciated.

It's perhaps not that surprising that you could create a capacitive microsphone from silicon, but what's mind-blowing to me is that it's such a good microphone. It doesn't seem obvious that you would be able to make a microphone that could do anything other than simply detect the presence of sound. Insane engineering to get to a useful microphone

It's amazing that even a crappy $10 pair of earbuds has this much engineering put into it.

The 3d model of the mic kind of blew my mind. I loooooooooooove seeing stuff under electron microscopes, thank you for making this. Fantastic all around.

I'm always blown away by how intricate fab stuff can get! way cool investigation

Absolutely crazy that something like this is 2x inside a $10 headphone, so each maybe 10cents, at most. 300mm waver gives maybe 50'000, so a whole waver with bonding and everything for less than $5000. That "buzzer" most likely is the battery, btw.

Excellent explanation! Never realised there was so much complexity in there, it's certainly a lot more than just a tinier microphone!

Wow, excellent presentation. The SEM images and CGI blend perfectly. What an amazing piece of technology. I wonder if the dimples in the top layer are for controlling the stiffness of the disk.

Also not a seasoned audio engineer here but my trivial explanation for the cavity below the membrane is, that it provides a neutral pressure reference against the outside. Thus the microphone becomes omnidirectional. If it would be open from the back, sound waves coming from the side would not be picked up. Thank you for that brilliant deep dive of a video!

such an underrated channel I have so many other things to do today but your SEM experiments just have me glued, amazing stuff.

Dude, this is awesome to see so detailed and even broken open. And on top of that, as if that wasn't enough, you explain it all as well and even use super beautiful renders for that explanation!

Thank you for making these videos. They really help give perspective on this extremely tiny yet extremely impactful part of all our lives. Plus the SEM images and CGI you make are absolutely beautiful to look at.

the way this microphone works is, there is a small hole that allows to equalize the pressure between the inside and outside of the chamber slowly later when pressure is applied to the top the fluctuations are relative to the mean pressure.

Fascinating. Thank you for the detailed explanation of how these mics work. Now I see my earbuds in a different way.

The amplifier for the microphone looks quite interesting too. Looks like too many parts to be purely an analog amplifier. I wonder if they're driving the microphone with AC and de-modulating to get the audio?

Man I am glad I found your channel. This stuff is awesome. TY

I work at a very old 200mm semiconductor fab as an equipment engineer. One of my processes is polysilicon deposition through LPCVD. Hearing these terms in a video about mics in earbuds is awesome.

You just spoke about almost every topic I had in my master's degree lecture "Physical Sensors in Silicon Technology", we also had the etching process RIE (Plasma etching - Reactive ion etching) explained in details in there. Thank you for making this video, I just finished my university degree and it's cool to see some practical stuff for a change!

These microphones typically have a digital output using "pulse density modulation", where the rate of toggles encodes the analog signal value. The three ports coming off the control die are almost certainly power. ground, and audio out. Also +1 for DRIE video. That was the first thing I noticed when you cracked it open. The Bosch process is cool!

Incredible video with stunning visual and intriguing explanation. Keep the good work.

Just insane the detail achieved and how simply such a complex topic has been conveyed. Your videos are incredible, among the best out there. 😮😮😮

Just one correction. The balls at the ends of the bond wires are tiny solder bumps and not Au balls. Solder bumping, wire bonding, die stacking and 3D packaging in general would make a great episode!

I love electron microscopes and pictures they produce. Really like to watch your content. I always learn something new. Thank you!

This was so fascinating to watch! Thank you much. I just stumbled accros your channel and you got so much more videos :O

I LOVE your videos. I learn so much. Thank you! 🙏

Nice work. This looks surprisingly easy to make.

What a perfectly paced video, I couldn't stop watching it. Thank for you the impressive images and insightful analysis!

EXCELLENT! This has been a long time coming. Thank you!

This is great! Hah, I just bought these ONN buds on sale for ~10$ and they work great as a basic hands/wires free headset. I was marveling at the amount of tech crammed into these cheap lil guys and you've revealed their innermost secrets :D Always enjoy your microscopy.

Oh wow this is amazing!! Thank you for making such a detailed video about it!

Your animations are fantastic!

Really enjoy all your videos mate, great work!

thank you for creating and sharing this, that was amazing and enlightening

What a fascinating dive into cool microscopic engineering. Great video all round!

Another incredible video! Thanks for the effort you put in

Amazing video ! Thanks a lot for all the time and effort.

incredible modeling and images, great explanations!

eally really cool, informative and educational. Thank you so much!!! I loved all the angles and even the 3D model that i have now idea how you got it. You, are, amazing!

This kind tech content is mesmerizing, I'm far from understanding how all this parts connect and talk to each other, but its exciting to see what can be done.

The pattern of the dimples is interesting, it seems like a thought through pattern, I wonder how much different patterns, depths and shapes of dimples would alter the sound.

I really needed a bit of marvel and wonderment today. Thank you!

Why there is such a big cavity: my guess is that it is simply to do with ease of manufacture. They first make all the structures on top, then flip it over and etch through from the backside. Importantly they also intentionally leave a controlled-size hole that allows internal pressure to equalize over a controlled time (e.g. if device takes a plane ride or happens to be put in a vacuum during further processing), not too slow but not too quickly that the device wouldn't be able to pick up bass. Given the tiny size of the cavity, it can't have anything to do with acoustic resonances.

This was on my feed since it was on KZfaq.. but was scrolling down.. but after seeing the reel had to watch the full video.. Absolutely amazing. The amount of tech that goes in inside 10 dollar microphone just blows my mind..

Super-cool indeed. Thanks for putting this together. It was fantastic for an audio nerd such as myself.

Superb tech and superb video! Thank you!

Really cool! Thanks for showing !!

Very cool video on a very cool topic close to my heart. Thank you for making and sharing it! I'm envious for the production value of your videos that is about 1000x higher than my MEMS microphone video series 😀 Cheers!

I’d love to know more about the hole pattern. Most is a hexagonal fill which is good for maximum density and uniformity. Edges are concentric rings, and in between is a hybrid.

Always a pleasure to see a new video from you.

Interesting to see the ridges inside that microphone cavity. At first i thought they were there to help with echo and reflections, similar to how some speaker boxes deal with it. Now I'm wondering if the etching process is calibrated to make those ridges a certain size specifically for essentially tuning it.

really amazing! thank you very much for all your great efforts! subbed! :)

fantastic video, I just found yer channel and I'm already liking it

Fascinating, great visualizations, thanks.

Really cool video dude! I just hooked up a MEMS mic to my WLED display for music reactivity. Cool to see exactly how these little pieces of “fly sh!t” actually work! Merry Christmas!!!

Intriguing stuff, keep em coming!

Absolutely fantastic as always! Man I wish I had and SEM to play with!

I look forward to these posts so much. It's the highlight of an otherwise rather mundate youtube experience for me.

Amazing video and produced! thanks!

This video provides a shocking amount of detail. Very impressed!

Holy moly the presentation and info is so onpoint

a very interesting topic covered very very neatly! good job :)

Your videos are amazing, thank you for them.

Wow. Super impressive video! I found those sem shots mesmerizing! There's such beauty at that tiny scale and it's amazing that mankind can build things that small! Thank you for all your hard work, and for making a video that was both entertaining and educational. 💯

It’s just FASCINATING to say the least to not only come up with such solutions but make them at scale for dirt cheapp! That work sooo well! The amount of research, knowledge, experience, and creativity of these engineers is legendary

really cool! I appreciate the source links in the vid

I could watch videos of you looking at the microscopic details in technology and explaining them forever! :)

I would guess the large cavity behind the membrane matters for the microphone's frequency response: Most practical microphones don't want to react to slow changes in ambient air pressure, because those can easily be much bigger than typical sound pressure levels, and could blow out the membrane. This is what the small hole in the middle of the membrane is for, to let the pressure equalize on both sides of the membrane (equivalent to a high-pass filter). Of course, if the equalization is too fast, then it can also equalize out low-frequency sounds, which would impact the frequency response of the microphone. The speed of this equalization depends on the hole size and the volume behind the hole (similar to a Helmholtz resonator with an additional loss term), so the manufacturer will tune either the hole size or the volume behind the membrane to set this frequency to a sensible value - I think 1-2Hz are typical for typical electret microphones. I would guess, then, that the hole is already as small as feasible in this process, for some reason or another. Then it would make sense for the manufacturer to make the volume larger (requiring more etching steps) in order to improve the frequency response at low frequencies.

Wow! Never seen this channel before. Subbed. Very cool

Sick, never knew how they fit microphones into those earbuds, thanks for showing!

This was awesome - I will be subbing!

Great video, earned a subscriber. Keep it up!

Thank you for the video it was very informative. You have put a lot of efforts in the making of it. I really love to know more about those micro chips, how do they work and it is really a marvel of engineering.

Why didn't I find this channel earlier. ❤ SEM's pictures are stunning

The quality of these videos never ceases to amaze me :)

MEMS is the quiet revolution. That tiny microphone, tiny sensors, gryoscopes on drones and modern airplanes, all done with MEMS. It started as engineers seeing other applications for IC processes than just electronics and making such things as working microscopic motors, but then quickly advanced to more useful concerns.

Great graphics! Good explanation!

Awesome video! Great work!

I'm curious about the details on it's response curve and if others can be made with different geometry with different curves. It's be cool to see tiny arrays of these that have insane sound quality.

This has answered questions I didn't know I had 👏

Very impressive!! Makes me want to buy my own scanning electron mi!😊

Im actually more amazed at the quality of this video than anything else.. and wow, SEMs have really improved over the last decade or so.

Man, you have access to some nice equipment. I would like to see the crossection of some region done by ion beam cutting. It would be slow as heck but nice. Very nice and informative video.

Thought I was subscribed here a long time ago… apparently I was wrong, so I remedied that and hit the like button while I was at it (I know I’ve done that before). Great work, concise explanations and descriptions that cater to the layman without condescending or even a hint of pretense in your tonal delivery. Kinda wanna have a beer with you, even though I hung up the drinking habit half a decade ago now. Keep up the good work and when I have expendable dollars again here in the near future, I’ll drop a few of them off over at your patreon. Until the next one, Bravo, good sir!

Gorgeous images!

Dang your channel is the coolest!

Thank you so much for creating this video ❤ It is really surprising to know that how these tiny devices are everywhere around us today and very few people appreciate the insane engineering involved in them.

Thank you for the video! very cool!

Very interesting. And amazingly well made video!

Love the work, will sign up for Patreon

Ordinary ceramic capacitors can also respond to sound. I've seen speculation that this effect could be used to turn ordinary electronics into surveillance devices but I haven't seen a proof of concept yet.

Wow, that was a truly incredible video. I was especially surprised and delighted with the model and animation you created to explain how the device works. I know that in terms of the principle of operation it is quite a simple device, but the scale of miniaturization and the way you presented it make me want to show it to my wife, children and friends. I am really impressed with your channel - keep up the good work. Regards

Wow, great dedication making the video.

ooh, your blender animations are getting really good!

This is such a fascinating video. Great contribution to science education!!!!

You are a great teacher! Thanks.

I absolutely love this channel