Cutting mirrors with Diamonds

Those tiny chips under the electron microscope are so cool!! Also a 2.5 micron finishing pass is INSANE. Great video as always dude!

Your method of using Blender to render the AFM height data yields the most professional looking height visualizations I've seen in my 16 years of science. After introducing you to optimal color map design, you're showing me new tricks. :)

I love how one guy in a garage have all this nice equipment. I am doing a PHD in experimental physics, and I have to make metalic pieces by hand, one could only dream!

What you're calling the "rake angle" is normally called the "cutting edge angle". Rake is the angle of the face that the chip rolls over, relative to the normal of the cutting plane.

No sponsor?? @KernMicrotechnikGmbH where you at? Get this man on a plane!

The microscope shots in your videos are always fascinating. It's a view that I never get to see in the rest of my life

Hey! If you're ever interested in other cool crystals (like big chunks of optical sapphire) I'd be happy to send you some.

Glad to see MCD and diamond machining getting the large scale attention it deserves. My master plan is slowly working 😁
Edit: Just got to the end of the video! Thanks for the holler!

this is the highest level of DYI

Ever since that short video few days ago I was eagerly waiting for this.. Amazing tech! Both what you did and what it's going to be used for!

If your metal is impure with gritty bits but you can machine extremely precisely, then maybe deposit some ultra pure layer on top and machine half of that?

Hi! Want to try something to improve surface finish with a MCDT? Coat the surface to be finished with a Sharpie marker.
Learned by accident from a co-worker that partially coated a surface. The blue spots of sharpie stood out, even if the tool cut the surface. It was shinier than the uncoated surface.
We then discovered that there is search papers written about surface tension induced by an adhesive ( such as glue stick, sharpie, paint marker,etc). It was found to improve surface finish.
Let me know if you try it 👍
As always, I really enjoyed your videos , fantastic work 🤘

It is amazing that such level of precision can be achieved on modern regular industrial cnc.

Love the way you present your work - very clear, no extraneous "noise". And nice results on the mirror shaping!

As a telescope mirror maker, I'm just screaming screaming screaming to finish it up with a very dilute cerium oxide slurry, haha.

Awesome work and fantastic visuals!My inner voice screamed when you lifted and reset the tool in the z axis over and over, I was so excited when you addressed my thought immediately afterwards and talked about the improvements😅

@0:33. THAT machine is what scientists use to create a Bose-Einstein Condensate. They use the lasers to cool down the sodium atoms and use evaporative cooling to do the job.

Just for fun did you checked that diamond in close up to see if it doesn't have any super small surface issues?

Wow dude, what an awesome video! The cinematography must've taken ages. Thanks for bringing the world of machining to life💪

I love the contrast where there's atomic force microscopy and that mist cooling setup in the same video.

How nice that quantum technology will finally be more accessible to us average joes. Dusting off my old 2 micron milling machine.

You have to machine it in one motion not swirling or back and forth or whatever you're doing, that's where you're going wrong. The surface must be milled to zero tolerance then slowly cut one pass but first put a bevel on the edge of the copper so you're not starting from flat and presenting a chip from the start. I've been involved in industrial mechanics and CNC machining for more than 30 years.

OMFG those baby curls!! :D I never thought I would think of a metal shaving as "cute", but here we are!

We found, when doing ultra high resolution scans, that the ball screw lubrication made a heck of a difference.

Sorry, your "Huge 8 micron" chips made me giglgesnort... These high precision tools and projects are amazing thanks for the vid.

Video sugestion: would be fun to see you rank your projects in a tier list. As you develop you workshop in the highest level of "DIYness" I think some of the projects have become, although amazing, so out of proportion from what mortals call a DIY that we cant even begin to apreciate your work the way we should. I think a tier list would be a good video to reconect with the mortal plane and maybe incentivise some of us to ascend too (Hope you don't mind the jokes). Could be in a scale of technical or theoretical difficulty, "coolness", satisfaction of the end result, affordability, etc. Anyway, your channel is awesome.

As a 20 year machinist that does the complete opposite end of the spectrum(I'll spin a 100,000lbs assembly on a 12ft swing lathe and take chips the size of your spindle), and I appreciate how cool this stuff is. I do some small stuff too, but the smallest is like drilling 0.015" holes, or holding +/-0.000¹", not a few nanometers lol

This is just so cool. Just a middle aged guy admiring your work.
I especially like how you talk through your process and problem solve. I'm sure many hours went into your research..setup..tests etc.
A admire your tenacity with a project like this.
Really cool to see. Thank you

Try Tellurium copper it is a free machining alloy. Some machines have servo amplifier gain noise that can cause the chattering or its just the ball screw bearings. If possible try cutting on the Y axis to see which axis is worse. Heck even a compound motion to see if it will eliminate it. could be machine harmonics. Great video !!!!

14:40 my face when microscopically planing copper with a single-crystal diamond tool gives you tearout like cherry burl.

19:17 Quality over quantity 👍

0:00-3:45 and as a CNC-machinist I'm already blown away... just WOW! Thank you for sharing this great knowledge in such immaculate quality, you got a new Sub ^^

We still have quite a lot of milling machines that technically use hydrostatic ways (they have central lubrication that maintains oil pressure) I’d claim. They have excellent stiffness and wear resistance when under high loads, such as stainless and hardmilling. As I can achieve 0,25um Ra in aluminium using non-polished carbide inserts, I’d reckon those machines would be absolutely perfect for making mirrors. Diamond MCD tooling is ubiquitous these days, but more on lathes than milling machines. Ive just never tried it.

This was really good. I watched your short video on these mirrors and had so many questions and doubts. You answered all my questions and doubts with this video. Nicely explained, excellent footage!

Absolutely amazing video, thank you!
The absolute thickness of the resulting chip isn't necessarily correlated to the absolute depth of cut - you can see this difference in your video where you cut metal inside an electron microscope. There are also some videos from roughly the 40s that show this. You can also tell some information about this from the texture of the inside of the chips - there is lots of compressive stress as the texture is very rough but the outside is smooth. That rough surface would have been smooth before the cut assuming you'd have machined it already (which you must have in order to get uniform chips to measure). This is perhaps a long-winded way of explaining why the chips end up coiled - because of the compressive stress causing the material to yield and permanently deform.

Dude! Those SEM pics. Wow.
Great work with the toolpathing

oooh sparkly

Dawg..... Ive only seen like 3 of your videos so far, but the quality is just insane. This is becoming one of my favorite channels

Probably an easier & cheaper method is sputtering copper\alum. over glass or sillicon wafer, then glue them to the a machined metal part with the correct angles needed. Consider that precision telescope mirrors are made this way.

This is fascinating. Flatness and smoothness is something I got a great appretiation of plastering a wall. Both together are hard. Those tiny cutting chips are so cool, Stunning micrographs. The shaping machine. Hand powered shapers are available, used to make geko skin moulds and internal gears. Analysis of chip thickness I've never seen before, the difference of the roughness of the two sides is amazing. To see the ball bearing difference and runout in the face was beautiful.

Don't forget, the ball screws are turned by brushless DC motors. Not steppers but still have a certain "step" to them based on how expensive the drives are. They are digital and will produce "steps" even if we can't see them or hear them.

Amazing video! Thanks for including all the images from your precision instruments. I'm still working in thousandths, so it amazes me to behold the world of micron scale.

The reason you can't find larger stock of ultra pure aluminum is because it's sale is restricted a bit since it is used in the nuclear fission field since aluminum is one of the few materials that neutron radiation doesn't cause to degrade since it returns to aluminum after it decays from being given all those extra neutrons. As such the smaller pieces are probably being recycled rapidly to keep the prices low so you aren't going to find cutoffs since collecting small cutoffs over time through multiple channels is one method to circumvent anti-proliferation treaties.
Again, people trying to kill each other ruins perfectly good science and economic solutions to problems.

The YT recommendations I receive are often mediocre, but once in a blue moon I get gems like this video of yours. Impressive!

what about using lapping to attain the final surface? something something 3 plate method, but with your stepped mirrors.. awesome stuff all the same, thanks for sharing ✨

Awesome work! Congratulations! God bless you! 🎉

8:58 TH-cam captions "Far Cry" with capitals like the video game.

I am so glad you are making this. You’re one of my favourites. Bravo.

I waa expecting a rabbit hole spin-off where you'd invent a piezo-driven nano clapper box to overcome the Z-error on retraction 😂.
Fascinating process and astounding work- got any video of the laser bouncing off the fresnel mirror?

I always love watching your videos twice, once on Nebula, then again here so that you can get more engagement.

Thank you so much. This is an absolutely amazing field of science 😁

This is so cool, I love seeing all the amazing tools you have and how sci-fi they all look.

Super cool video and very clearly explaned!

You make a lot of neat videos, but I think this might just be my favorite one yet - hitting that precision machine design part of my brain just right!

Wait, is that a HongDian blackforrest in EF? That is a very nice choice of pen! What is your ink of choice?

Very cool video! I was initially interested in your channel from your early machining videos and this was super cool to see it tie into that stuff.

You can braise diamond?!

15:45 chip analysis is something i hadn't considered. Very cool.
Using the thickness of the chip as data. Clever.

we all know that the acronym of MOT belongs to the Microwave Oven Transformer because it is more common and has actual use cases

keep doing what you're doing, its super appreciated, shine on you crazy monocrystalline diamond!

Nifty AF ! & Cylo is very much sub worthy.

Sunshine is delicious, rain is refreshing, wind braces us up, snow is exhilarating; there is really no such thing as bad weather, only different kinds of good weather.

I love that the internet has enabled us to do things like crowd-source the funding for a postdoc in materials science and metrology.

Damn I'm amazed with all the equipment you have

As the video was going I was doing my own commentary, then as it progressed you addressed what I was saying. I had to make a part for a very well known "Place" we will say. I have a small desktop sub 200 pound aluminum framed machine. Its highly accurate, but with the specs on the part I was doing I found that if I heated my machine in an enclosure just above 300 degrees F I would not get any thermal expansion. It took me over 3 months of trial and error to machine pillars in a substrate that was less then 25 microns tall. You did a great job. One thing I did have to do and was thinking a solution to the differences in copper harness was tempering each substrate before trying to machine them. My though was "Level the playing field"

this is so fucking good and packed with information. but i never got bored. you jsut added weirder and weirder tools.
"ill just pop it into my electron microscope. i never leave home without one."
-Oh whats that? in my other back pocket?
- "oh thats just my atomic force microscope, had it since i was 12"

Being able to see things like this that i didn't know existed and is so niche and fascinating is why i love youtube

Very cool video, love this.
I feel like having the metal colder would help bonds be stiffer but at the same time more stiffness would make jaged breakouts. Warmer metal would be softer but then you form pools of metal that bunch up in front of the tool.
What if everything was very cold but introduce very high vibration on the head so you only heat up whats being scraped off the surface.
Optics are tough, this was a great watch and gets the brain going to achieve the ultimate finish.
The vibrations will probably cause so many other issues in surface finish. Just due to the tooling bending from side to side chaging cutting angle and the inertia in the tooling machines... would be awesome to experiment like you, this is a very rewarding experiment!

6:39 the following part almost fits to the rhythm!
Amazing technology. I can only try to imagine what we could make with that. Like tiny versions of bigger instruments, without much more engineering but magnitudes of order more precise.

Simply incredible.. Your content continues to astound me on every new video you release. [Chef's kiss]!

Brother, the fact that you are using a stone tool to make a crazy precise scientific thing is humbling and beautiful.

I liked the video, the explanations are spot on!

From my brother.....
That is quite interesting and very cool. There is one more thing that might have caused his wavy appearance - stiction (caused by the co-efficient of friction being higher when stationary than moving). I remember from reading an Amateur Scientist in a Scientific American way back that there are materials that have, in effect, negative stiction (where the coefficient of friction is less when stationary than when moving). The guy in the AS article used that type of material in effect as the “ways” on his scriber for scribing a diffraction grating.

This is impressive. Even more being it's your own setup. Diamond turning is a really interesting method of creating optical surfaces, and I'm very interested how your v1 trap worked out!

Your patience is legendary!! Great video

Your videos are always so beautiful. I can’t thank you enough for putting in the effort you do.

A real pleasure to watch! Thanks a lot for sharing such a great content. Please keep up the good work!

Watching you do stuff that I'd never consider in my wildest dreams to be DIY possible gives me similar feelings to watching Mythbusters back in the day. I'm just amazed.

Never thought I would be interested in cutting mirror surfaces with diamonds, yet here I am wanting more!

Everything in this video is peak awesome!

the coolest part of these IMO is how strong the binding is between the carbon lattice and the metal that holds the cutting bit.. Basically the carbon lattice is formed electrochemically and this essentially works as the strongest glue ever

Dude, your channel is always a pleasure. This video was a blast.
Those microscopic chips are so cute.

I swear that I learn something new with every video of yours I watch.

This video rocks love your voice over and you sharing this for free is gold you get a 10/10

Loved seeing that fireball tool vid, love his channel!

My jaw was on the floor with your opening shot. Fascinating stuff to someone whose run-of-the-mill surface finish is a 4" angle grinder or maybe the da sander if I'm feeling particularly fussy. Appreciate your output fella, keep it up! ✌ 🇦🇺

You set the bar SO High for the rest of us. Well done dude! Well done! 😎👌

The humble hardworking genius is back at it again, doing things that the majority of us had no idea were even possible. Some banger tunes on this video too. I had to Shazam the outro song.

We are cutting lacquers and DMM copper plates with diamond cutter with 3μm rim. With that knowledge available from record cutting the procedure to determine the optimal rake angle of the cutter to avoid the chip being a problem is known in our craft You do almost do the same thing , just in a different field and down to the nanometer dimensions. - we remain just about still in the μm world - well done, great what you proofed and found independently and a worthwhile video

Having heard you talk about the temper of the copper stock it occurred to me that it would be easy enough to anneal the copper stock by simply heating it with a torch until it's red hot and letting it cool back to room temperature on it's own. This insures consistently soft material to work with.

I cannot get over those perfect chips starting at 17:00. Great work!!!

Those little copper chips were cool, thanks for taking the time to share that. Charles

I've logged in to say that this is sick and you should make a movie, not snow white but you're half way there on the mirror part.

It's so amazing to see at the microscopic level in HD. Crazy :)

This is excellent, other than using metric lol
Regarding the end goal of this process, that's fantastic, there's no reason we should have to rely on others to discover when we can figure things out ourselves! Indeed realizing that soon if not already humanity will be able to precisely measure the universe and it's gravity has so much potential. The more people and locations that can measure info, the better we ll understand reality, what makes it shift and change place to place moment to moment. Yet Man must develop percision as to peer deeper into the void, which entitles it's own developments of comprehension, exactly how this video shows a solution needed and progressed towards it. having stated that, Man need not measure and record things to know it, yet allows him to lock in those results to reality and build upon those details.

That spiral chip is so satisfying to watch, and darn is that surface finish good. I'd have thought you would have run into the limits of the machine with a finish somewhere near the first sample you showed, those early samples for a normal mill where already really quite good. So I'm really impressed how much further you could get it with some thoughtful iterations on the techniques - I don't think I'd have even thought to try and push that machine that far (though my experience may be marred by the comparative low quality of my mill). Still with the goal of a mirror in mind I think I'd have have been using the CNC to rough cut the blanks and create a bespoke shaper to do the final finish with...

Keep kicking ass man this video was Amazing.
YOU did a great gob on it

Watching from Kenya. Long time fan. Your videos never disappoint 😄

Absolutely love your video(s)! A lifetime ago, I used to help build and design AFMs, and it's so cool to see how you've used yours."

I paused your video when you mentioned hydrostatic bearings to go learn more about it and then deja vu when I got to the ending of your video to see Cylo's footage that I just watched!