What are those little "whiskers" on the diamond? Carbon adhesive goop, just an artifact from imaging 😅 I scanned the top of the diamond, then rotated it to get more of the profile. Apparently the carbon adhesive dot that's used to hold it down left some whiskers of polymer behind after I rotated it. Meant to put a caption on screen about that, but totally forgot!
The chip research group I used to work at used a focused Ion Beam (FIB) to do chip repair and modification for prototype chips. We can go in and even deposit resistive material, or build up entirely new probe pads to connect to the center of a circuit to debug things. Pretty cool stuff, very expensive machine. The dummy filling process has made it much more challenging to get to the lower metal layers, and as a result we have to be clever about it when we etch or design.
Super cool! FIB is such a neat technique in general, but really cool that it's used to repair or alter chips. The deposited material is done by GIS right? Inject a gas and let the ion beam chemically alter/bond it to the sample?
@@BreakingTapsI'm not really that familiar with the practical process - I was lucky enough to never need my chips tinkered with after we got them back from the foundry. We have one guy in the group who is the expert and spends a lot of time on the machine. There is a lot of 'Fingerspitzengefühl' involved with getting all of the parameters working optimally to get good etching and so on without destroying the underlying chip through stress etc. Main way I have seen it used a few times is to kill unwanted oscillations in unstable millimeter-wave amplifiers. At some point someone was even putting in resistors to reduce gain (and thus chance of oscillations) that could be connected if there were some issues after manufacturing. You can also trim resistors with it, but usually it is much easier to do that with a laser - unless you need to be really precise, or want to deposit too, using a precision laser to cut traces is much more (cost) efficient. Added bonus that the learning curve for the laser is sufficiently low so PhD researchers can operate them by themselves, unlike the FIB which requires high vacuum, expensive gas mixtures, and in general a lot of training. I remember a situation where a researcher was building custom diodes for plasmonic detection from scratch, and each diode involved >5kUSD worth of tungsten-deposition gas or something.
@@BreakingTaps The precursor gas (e.g. W(CO)6 for tungsten deposition or XeF2 for silicate etching) sorbs onto the surface, forms a monolayer, and reacts slowly or not at all until activated/decomposed by secondary electrons from the ion beam scanning a particular part of your sample. So for deposition you get W (and some C and O impurities because the process isn't perfect) on your sample surface with the CO sucked out by the vacuum system. For etching, the F2 reacts with your sample and the Xe is removed. You can get the same effect using the electron beam in a dual beam system (or even a SEM with GIS - a rare but not unheard of combination) but it's much slower than with FIB due to the lower activation energy and beam current. It's sometimes useful for things like protecting super fragile samples with a thin metal film before doing more deposition with the ion beam, or doing chemical staining (with no sputtering) to selectively etch regions of a sample.
a little something so u can add to the "buy a new/larger/fancier ion milling thingy". sorry in advance for how little 10 bucks of my country's currency actually worths in USD 😅
Really nice work with the Blender viz in this video - Blender's particle engine and the molecular script can be a pain to work with, but you got them looking great, and even showing real-world behaviour!
@@BreakingTaps you should definitely be happy with it! If you’re interested in some more blender science visuals, there was a fantastic talk at the blender conference last year about rendering proteins at world-record speeds. It’s up as a VOD on the Blender youtube channel.
Awesome blast from the past! I used the exact model of machine for my university diploma thesis some 20+ years ago. It had the roughing pump (a diaphragm style pump inside the case though). Brings back memories... Hours and hours of disassembling and cleaning the etching gun, even the tiniest metal flake could short out the HV.
The thing I absolutely love about this incredibly underrated channel is that I learn so so much about things I wasn't even aware existed. And even for things that aren't even covered but merely mentioned, allowing me to delve into another subject on the internet. Thank you so much for what you do. You are a treasure.
I remember using these all the time during my doctorate program. I took so many cross sections of through-silicon-vias (TSVs) and surface micro-bumps, testing ways to stick chips together. I also remember using these machines to place in some "bodge wires" and fix up some very tiny pads (even sometimes those little bumps themselves) on prototype dies. Fascinating machines and incredibly powerful tools in the semiconductor world, but I've very glad my work is all computational now, as these things take forever to go from step to step compared to logic and signal simulations I can just let run.
Never a dull video, it's awesome knowing I'll learn something super cool when you post! I wonder how feasible making a motion system for it would be, maybe nab the JWST flexture mechanism?
It has definitely crossed my mind! Would be nice to replace the existing sample stage (since it's missing parts already), so might be neat to replace it with a little XY stage
You have two main knobs to control etch rate in different materials: * Incident Angle: Metals etch faster with a normal, or head-on angle. Polyimide or photoresist etch fastest at about 60°. * Relative Mass: Matching the mass of your ion to the material to be etched can change the selectivity. For example, choosing a high mass noble gas could increase the etch rate on your tungsten while decreasing the rate on aluminum. I have to compliment your atom-on-atom model of the interaction during etch, it was beautiful. One thing though: regardless of incident angle the ejected atoms tend to leave normal to the surface, with a population distribution that falls off with the cosine of the angle away from normal. There is a small population tail opposite the incident angle of the beam though. This is because the momentum is transferred into the surface and the subsurface atoms reflect it back to the surface.
makes sense if you think of it, like a captive poolball, there's really only one way for the ball/atom to go, and the remaining energy is dissipated through the structure as heat.
You should never ever attempt to run a turbomolecular pump in air. These devices are designed for removing most of the remaining particles in a fine vacuum to achieve an (ultra) high vacuum and turn at ultra high RPMs. Running them in air (or any other relatively dense gas) will easily overwhelm the mechanism and crash the whole thing. Also, Argon molecules don’t exist - as a noble gas, Argon exists only as single atoms ;). But don’t get me wrong, this was a great and very informative video!
Work on some turbopumps, and you find that they only ever run at a few thousand RPM in air. They stay cold. The air-drag prevents their speed from rising (at least it does in the 4in types, TPH-240 etc.) Problems do arise if they're at normal operating speed, and you accidentally vent your chamber to ambient pressure. That can give you destructive disassembly, and that's why turbo pumps are always bolted to the chamber (or bolted to the roughing pump cabinet.)
Yet again you show me one of the cooler things I have seen in awhile. (The last was that stop motion animation using the electron microscope.) This really is a neat bit of kit.
Yeah in retrospect I should have filmed some of that. Was just deep in debugging mode and didn't think about it. A lot of the issues ended up being related to the vacuum gauge (it was _really_ dirty and needed cleaning). The reported vacuum level would sometimes fluctuate wildly, which would confuse the machine and think the airlock mechanism had triggered. That had all kinds of effects like turning off the HV supply, messing with the turbo, actuating the airlock vent, etc. The rough vac pump needs a new diaphragm, so I just replaced it with my other pump for now. Some of the needle valves needed cleaning, and the ion guns needed cleaning too (they get really finicky once material starts to build up, especially insulators). And I think the bearings in my turbo are dieing, but that's a problem for a different day :)
@@BreakingTaps I totally get that filming everything while you're trying to think and troubleshoot is probably kinda annoying. However, I would definitely have loved to see some more "behind the scenes", even if it's just filmed with a lower quality camera (which could perhaps make it less of a nuisance for you). --- rambling continues --- While the results are really cool to see, I'm almost more interested in the process. For example, I have a Pirani gauge that's behaving kinda weirdly, and was considering trying to clean/fix it, although I'm not sure if that's even possible - most sources just seem to say that you should be real careful with them, and that's about it (i.e. probably impossible to fix/clean). I'm guessing the vacuum gauge you're referring to is a different one since you go down to ⁓10e-5 Torr, so it probably wouldn't have mattered, but it's just an example of the kind of small things that can be really useful to some people. Sadly that level of detail probably doesn't attract quite as many views, though.
this is super cool, I've used these tools to design transducer biosensors but we referred to them as plasma deposition sputtering machines. Applying atomic coatings of gold in specific ways. Really incredible to see electron microscopy of it though!
We used to have an ion mill for making 3d models of geologic samples for oil and gas reservoir characterization. Basically it would mill down a layer of material, do a scan with the microprobe, then rinse and repeat. Stacking all the scanned layers together got you a pretty decent 3d model of the sample.
The info is awesome, the ion mill is neat, but the animations are incredible! They make the subject matter so much more understandable. Thanks for all you do!
Those scratches at around 9:30 can be avoided with good mechanical polishing practices, it does not need ion milling... Struers OP-S colloidal silica with the appropriate polishing cloth (MD-Nap or MD-chem) can easily give you the desired results. Ion milling, or more precisely, focused ion beam (FIB) milling can also give more. For example, you can dig out small lamellae for TEM investigations. I used to make them, they were typically 10x20 um large and approximately 100 nm thin at the end of the procedure. The thinning was also done by the FIB, it was a very gentle (and time-consuming) polishing. Also, it is a great method to increase the "resolution" for element analysis (EDS/WDS) in materials. One can dig a cross-section of interest with the FIB, then can dig a trench a few micrometres behind the cross-section. This effectively decreases the volume where the X-ray photons come from, thus the analysis will be less "noisy". Oh, yes, the FIB I used was using gallium for milling and then I could also use it for deposition, but then it was either carbon or tungsten.
I really enjoy working on black boxes. A couple years ago I got a helium leak detector from the late 70/early 80's working, and now I am working on a home project to get a HPLC from 1997 up and running. The ion mill sounds like a lot of fun.
I've been amazed by what you accomplish in this channel. Wheter with a team or by yourself, it is amazing to see how one's effort combined with the wide amount of information can lead to something that would require a whole research group. Congrats!
*ONE small* thing to add: Diamond etching/polishing has worked in your case because the diamond particles you bought were not of a high grade purity and crystalline uniformity. In the latter case it would take way, way longer before you could see any noticeable result. To speed it up, you might need a much more powerful/plentiful ion guns.
Awesome video. I've ben exploring sputtering osmium targets and trying to grow crystalline samples in a quartz furnace. Thanks for the tip about the analog controller. I was able to use the old thermal couple it improved my results by several factors. Extreme control over the temperature has solved the growth rate and size. Thank you again 👍
I had a summer internship working with one of these Gatan PECS system. I used it as a polishing system for EBSD samples. I was using it at very low currents. It kind of works once you get the recipe right for your material system. Thanks for the video!
Wow, this is insanely cool! (Fantastic vid as always too, the animations were great!) I hadn’t been aware of ion milling before, nano-polishing optics for final figure correction seems like it would be an orders-of-magnitude improvement over conventional mechanical polishing. I toured a Panasonic lens factory a number of years ago, and saw them hand polishing(!) the tungsten-alloy molds used to make aspheric lenses. The aspheric profile of the mold is formed with a single-point diamond on an ultra-precision lathe. These are quite accurate, but the problem is the diamond tool leaves behind a nanometers-deep spiral groove that can result in ugly “onion-ring” bokeh in the molded lenses. (Bokeh is the term for how out-of-fossil objects are rendered by a lens. Onion ring bokeh makes the big soft background blobs from out of focus background lights in a scene literally look like slices of onions, it’s very ugly and distracting.) They fixed this by *hand polishing* the molds. A worker would wrap a cloth impregnated with ultra -fine diamond abrasive around their fingertip and very gently rub the surface of the tungsten blank to polish away the grooves. They had a high resolution surface profilometer that they used to check their work, taking many passes on different parts of the blank to both remove the grooves and maintain the aspheric profile. It was incredible that they could do this manually to a precision of 10s of nanometers, and at the time it was a trade secret of Panasonic’s. A couple of years later it became standard industry practice. This seems like a perfect application of Ion Milling, I wonder if that’s how it’s done now? The next time I am talking to a Panasonic optical engineer I will ask him. A quick question: What’s the schmutz on the unmilled surface of the diamond on the left side of the frame at about 10:44 in the video? Is that just surface dirt or is the diamond itself that irregular due to poor polishing? What a great toy! (It a,so strikes me as an incredibly cheap way to get a high-vacuum system driven by a turbo pump 👍😁)
For the rough area at 10:44, at the far left of the frame that’s what random carbon gunk (think oils, random grime) typically looks like in an SEM image. Much closer the etch interface, there may be some roughening due to redeposition of sputtered atoms, or may be roughening in a region which received a low flux of ions near the edge of the main beam.
This video was incredibly well done and brilliantly articulated. I’m not an expert in any of what is being discussed but, I at no point felt overwhelmed by the information being discussed.
I was prepared to watch a video with a bunch of cuts of any material and what I got was a guy talking about cutting and then some 100 microscope zooms onto some random stuff that I didnt care about at all. Keep up the good work 🙂
I work on and teach ion implanter theory for the semiconductor industry and one thing to take into consideration is the process gas used (hydrogen or helium are the most dangerous) can cause x-ray, gamma and neutron radiation when interacting with certain materials like boron in graphite. I doubt the extraction voltage is anywhere near the levels that can cause radiation but it is still possible. When talking about angular etching, this is also applied on silicon wafers during implant. Depending on the material composition at the atomic level we will twist and rotate the wafer to help mitigate what we call channeling where ions are driven deeper in between the crystal lattice. And yes, the nitrogen layer could very possibly be a titanium nitride, tantalum nitride or any other combination. These are typically used as barrier or glue layers to help prevent the attraction or repellent of certain materials based on their interaction with one another.
Even as an Electrical Engineer (currently doing my master's degree) specializing in Semiconductors I'm very impressed by your abilities and the accuracy of the presented content. Nice job and fun to watch!
Humanity has created such amazing tools. Not just this ion mill but also the microchips we tend to take for granted. Precision engineering doesn't begin to describe these marvels. It's incredible that we all carry them around in our pockets.
If you’re super unlucky, then when you set your alarm to 8:45, you go to the size of atomic level at random TV pops up in front of you and shows rickroll dance
It's incredible how those etched microchips looked like alien city-scapes. I could imagine some kind Giger-esque figures coming and going along the "streets" or in and out of the "buildings". Honestly, I could watch those close up pictures/videos for hours.
If you put the sample at a very shallow angle to the beam, you can do very fine polishing to reveal crystal sturctures, nano-porous features, etc. Pretty cool technology!
I (and two other engineers) built a two axis ion milling machine in 1995 for computer controlled figuring of optics for semiconductor production. I did the software and process development for both metrology and figuring. Some optical glasses are very heat sensitive, so it was necessary to limit beam energy. Also, maintaining a constant ion beam shape and current over many hours was quite challenging.
Oh wow, super cool! Yeah I can imagine making the process reliable and repeatible is really challenging. My machine is very fiddly and easy to go from a beam that is over-etching to one that extinguishes itself. I can't imagine the engineering needed to make the system work reliably. Really neat project, especially in the 90's!
@@BreakingTaps You've got to maintain a good vacuum with no contaminants. Filament burns out quickly otherwise. I used a 4 variable partial factorial experimental design to get the 2 electrode currents and 2 argon flow rates to optimize the stability and gaussian shape of the beam. There were trade-offs between maximum removal rate and shape/stability. The latter is more important. The better the beam matches the model, the faster the part will converge to the desired shape. Oh yeah, pitch polished glass has different surface layer characteristics for a few 10's of nanometers than the underlying bulk material. So the removal rate on the first run of a pitch polished surface tended to be low. So you needed to be careful as the removal rate often increased after the surface layer was removed. Even so, removal rate was hard to predict, and had to be measured in process on each workpiece. We needed to hit surface shape uncertainty around 2 nm rms.
Whenever I see setups like this, I wonder if you have a vacuum buffer, or if that's even a thing. My idea is to have a tank several times larger than the test chamber. When it's time to run the sample, you can purge the test chamber into the vacuum reserve tank (fun to say) to reduce the gas pressure by the volume ratio of the two spaces. Then you'd be able to run a turbo much sooner, or do 90% of the pumping in the first couple of seconds. A separate pump of even mediocre grade can prime the tank again, while the main system runs on it's own; it doesn't even affect run times. You could even pipe it out to multiple locations, with check valves for sudden pressure failures. Cheap video idea, but more runs per day sounds better too.
TBH I'm still not entirely sure what was wrong with the turbo. A lot of issues cleared up once I cleaned the vacuum gauge... I suspect it was giving erratic readings and really confusing the simple state machine that runs the machine. Occasionally the pressure gauge would swing wildly, and then the airlock mechanism would actuate which would cause an actual pressure change, etc. So I'm thinking the turbo might have been instructed to turn off because it thought the machine was in a bad state or something.
Ha, I made so many samples using this Gatan Ion miller in the grad school. Good old days. Very innovative design. Used to clean those guns every 2-3 days.
I used to work in a lab where we prepared samples of films used inside batteries with ion beam etching. For this we made super high aspect ratio cross sections of that film, up to 200:1 so they could be studied in an transmission SEM. A nice trick was that the etching could also be done inside the SEM, which is great news, because it was near impossible to take the samples out of the SEM without them blowing away at the lightest breeze because they were so tiny.
00:50 turbo molecular pumps don’t work unless there is a roughing vacuum in the chamber, your turbo pump controller won’t let your turbo pump’s blades to rotate if you try to power it up at the atmospheric pressure.
This machine has a "dumb" turbo controller and will happily spin it up to max RPM (or at least try, and burn out the motor in the process if you let it) 🙂
This is super interesting and neat to see. But to be honest, the part I'm most curious about is HOW they were developed. Like for example, the Magnetron... How do you discover that if you shoot electrons in a single direction, get them to start spiraling, and put them next to specifically sized cavities, electric fields will start to oscillate at a desired frequency and emit EM waves of that frequency?
I thought that you weren't supposed to run turbomolecular pumps in atmosphere, the pressure should be lowered with the roughing pump first to prevent damage.
We have huge sputtering coaters at work and the engineers talk like this all the time. We also have an electron scanning microscope which performs miracles often. I've been getting some engineering training on the coaters lately so I can be some help during problem times and take on some improvement projects. I looked down the site port the other day and saw that beautiful plasma, mesmerizing!
Yep! They are optimized slightly differently (i.e. no need for a focused beam on a spacecraft) but fundamentally same idea! This particular gun is a very close cousin to the very common hall effect thrusters used on a lot of satellites.
At work I had a lot of options from 'wrecking Ball' Caesium Ion Sources to very energetic Oxygen Ion sources (which ate filaments !) down to very light Ion's. We had a FAB process (Fast Atom Bombardment) where we set up the Ion beam focus and all that good stuff then passed it through a charge exchange cell (more gas) and you end up with a neutral beam. This was great as one of my favourite studies was 'Depth profiling using Ion Milling to dig the hole, fascinating when using complementary techniques of analysis (SIMS or ESCA) and working your way through a piece of magnetic tape from a video cassette looking at the best bit, and that was the 'Interfaces' of the various layers. This is a stunning video so Kudos there ! and there aren't enough channels for us ' Nano Nerds' anyway !!...cheers.
If you want to etch diamond CBN or anything else that is very hard, add a few percent of either oxygen or hydrogen. The texturixing etch followed by ion implantation is an important step for solar cell manufacture as it greatly increases the surface area of the cell. ❤
Sometimes I think there is a guy working at youtube specifically selecting and recommending the best videos and channels for my personal benefit. Great video.
The tungsten micro-masks remind me of the sandstone pillars (hoodoos) in the American southwest. A tall pillar of soft rock capped by a hard stone, molded by the rain.
I managed to drill a hole in 1mm glass by similar method. After repeating a few times, the tiny pore actually became visible to human eyes. PS, with a focused beam, the micro-hole drilling is used for making thin samples for TEM microscopes. Scan the FIB ion-beam to drill two adjacent square pockets in your solid sample, with thin walls or "lamella" between. Break it out with a micromanipulator. It's not nano-sculpture, it's just sample-prep. Heh, TEM microscope. FIB beam, LCD display, HIV virus, PIN number ...that's the RAS syndrome, meaning, redundant acronym syndrome syndrome.
My scanning electron microscope has an detector which can identify the energy of x-rays, and uses a technique called Energy-dispersive X-ray spectroscopy (EDS / EDX). If you hit an element with a highly energetic electron, it will sometimes emit an x-ray. And the energy of that x-ray depends on the atomic properties, so each element has it's own "signature" of x-rays that are emitted The EDS works by slowly scanning a high energy electron beam across the sample and collecting the x-rays that are emitted. It then looks at each pixel and determines what mixture of elements are present based on the x-ray signatures at that spot.
Not sure of the type or manufacturer of turbopump but I would refer to the manual - you may be causing overheating or mechanical stress if you ran no load in atmosphere
Your content is amazing and I love that you endorse Rust. Good luck with all your amazing projects, I am sure it will be part of the inspiration for my own.
I suppose it's a bit like an ionising laser, but is a lot more precise, similar to use obsidian for surgical instruments, instead of traditional steel scalpels.
you could also use a soft electron/ion beam to cure an etch mask, so you dont destroy your main high precision etch mask with the electrons/ions, you know the spin sludge on the silicon wafers, then remove any uncured parts of the temporary cured mask, then do the actual hard electron/ion etching, ie to keep the original mask intact, to support multiple copies of the same pattern reliably. industrial processes rock. not sketchy at all.
Hi Breaking Taps, Super nice and interesting video. Just a simple question-idea. I'm a (bio) chemical engineer specialized in organic chemistry, but I do love technology. Into chemistry, it is wel known that gases average (quadratic) speed depends on atomic mass; so hydrogen diatomic gas (H2) moves faster than Helium, than dichlorine (Cl2) or than SF4; and speed depends also on heat (molecular agitation, and free move traject in Brownian agitation), just like pressure (number of molecular shocks on the wall's surface). So here is my question: You used Argon (MW 39,95); but what if you used Helium (MW 4,00) or Xenon (MW 131,29); whould that mean that those inert gases would be also accelerated to atomic blast; but Helium would be accelerated roughly 10 times kinetically faster (but with different impact force due to F= mass*(impact deceleration)) and Xenon about 5 times slower but much eavier thus providing very interesting different abrasing results than Argon. Regards, PHZ (PHILOU Zrealone from the Science Madness forum)
Are these circular marks on the etched surface (especially visible on the Diamond) the impact craters of single argon atoms? I find that somehow hard to imagine, they look pretty large.
I think that's a mix of crystal orientation and local topography. Different crystal orientations of a material will etch at different rates, so big hunk of diamond for example will be a mixture of different "grains" (unless it's monocrystalline diamond). And some of those grains will etch faster, leading to a pit. And local topography can affect it too. If there is an existing pit, that'll tend to grow faster than a flat area (more surface area to get etched). Or if one region is facing the beam a bit more, it'll etch faster. Ditto to impurities that might etch faster. So yeah, it's a combination of stuff, but definitely not individual impact craters. Too large as you said! 👍
Carbon adhesive goop, just an artifact from imaging 😅 I scanned the top of the diamond, then rotated it to get more of the profile. Apparently the carbon adhesive dot that's used to hold it down left some whiskers of polymer behind after I rotated it. Meant to put a caption on screen about that, but totally forgot! I'll pin a note about this so others know 👍
Tip: Find a linear induction and maglev motor bearing for the turbo motor (I'm assuming vacuum motor). It should last a very long time. Like transistor radios, they should become ubiquitous very shortly. About 7-11 levels of contrarotating blades (think planetary gears) should bring you to about a 99.987% vacuum. But why stop there? Between metallic printing and 23 contrarotating blades (yes, all, no stationary, all with electromagnetic (gasp!) planetary gears, the entire system has zero contact friction, albeit some loss due to hysteresis, so it should be darn neigh indestructible, right? Pull the vacuum, stop it off, conduct the experiment, then repeat as necessary, ad infinitum.
What are those little "whiskers" on the diamond?
Carbon adhesive goop, just an artifact from imaging 😅 I scanned the top of the diamond, then rotated it to get more of the profile. Apparently the carbon adhesive dot that's used to hold it down left some whiskers of polymer behind after I rotated it. Meant to put a caption on screen about that, but totally forgot!
You read my mind. I was wondering what those things were.
Thanks for the explanation and thanks for another really interesting video.
Very epic, be interesting to see what else you can do with it! ❤️🔥🫡
I appreciate the 30uM rick roll. Good stuff. Looks like a fun new toy.
In 3D printing terms, we call that "stringing". In Ion Blasting terms, we call that "no damn clue"
7:50-8:10 How do you analyze the sample for different elements?
The chip research group I used to work at used a focused Ion Beam (FIB) to do chip repair and modification for prototype chips. We can go in and even deposit resistive material, or build up entirely new probe pads to connect to the center of a circuit to debug things. Pretty cool stuff, very expensive machine.
The dummy filling process has made it much more challenging to get to the lower metal layers, and as a result we have to be clever about it when we etch or design.
Super cool! FIB is such a neat technique in general, but really cool that it's used to repair or alter chips. The deposited material is done by GIS right? Inject a gas and let the ion beam chemically alter/bond it to the sample?
Did not know it is possible to repair a chip. 🤯
@@BreakingTapsI'm not really that familiar with the practical process - I was lucky enough to never need my chips tinkered with after we got them back from the foundry. We have one guy in the group who is the expert and spends a lot of time on the machine. There is a lot of 'Fingerspitzengefühl' involved with getting all of the parameters working optimally to get good etching and so on without destroying the underlying chip through stress etc. Main way I have seen it used a few times is to kill unwanted oscillations in unstable millimeter-wave amplifiers. At some point someone was even putting in resistors to reduce gain (and thus chance of oscillations) that could be connected if there were some issues after manufacturing.
You can also trim resistors with it, but usually it is much easier to do that with a laser - unless you need to be really precise, or want to deposit too, using a precision laser to cut traces is much more (cost) efficient. Added bonus that the learning curve for the laser is sufficiently low so PhD researchers can operate them by themselves, unlike the FIB which requires high vacuum, expensive gas mixtures, and in general a lot of training. I remember a situation where a researcher was building custom diodes for plasmonic detection from scratch, and each diode involved >5kUSD worth of tungsten-deposition gas or something.
@@BreakingTaps The precursor gas (e.g. W(CO)6 for tungsten deposition or XeF2 for silicate etching) sorbs onto the surface, forms a monolayer, and reacts slowly or not at all until activated/decomposed by secondary electrons from the ion beam scanning a particular part of your sample.
So for deposition you get W (and some C and O impurities because the process isn't perfect) on your sample surface with the CO sucked out by the vacuum system.
For etching, the F2 reacts with your sample and the Xe is removed.
You can get the same effect using the electron beam in a dual beam system (or even a SEM with GIS - a rare but not unheard of combination) but it's much slower than with FIB due to the lower activation energy and beam current. It's sometimes useful for things like protecting super fragile samples with a thin metal film before doing more deposition with the ion beam, or doing chemical staining (with no sputtering) to selectively etch regions of a sample.
@@AndrewZonenbergHah, Fancy meeting you here!
a little something so u can add to the "buy a new/larger/fancier ion milling thingy". sorry in advance for how little 10 bucks of my country's currency actually worths in USD 😅
Those cross sections look incredible and your animations from Blender are great. Thanks for sharing.
ngl, the animations were one of my favorite things in this video!
Robo Zollo mass commenter strikes again.
The world needs more of this and less noise. Incredible stuff as always.
Really nice work with the Blender viz in this video - Blender's particle engine and the molecular script can be a pain to work with, but you got them looking great, and even showing real-world behaviour!
Thanks! Definitely took a lot of tweaking and fiddling to get it doing something close to what I wanted. But pretty happy how it turned out!
Wait, what?
You can simulate particle physics in blender?
I’ll Google it later…
Any pointers or code?
@@BreakingTaps you should definitely be happy with it! If you’re interested in some more blender science visuals, there was a fantastic talk at the blender conference last year about rendering proteins at world-record speeds. It’s up as a VOD on the Blender youtube channel.
broo where u get that pfp? thats so fricking cool
@@dewakbarr i made it! in blender :D its from a short film on my channel
Ion thruster but confused
0:24 edge any surface huh?
🥵
🤭
It'd be really cool to have a video series following you troubleshooting lab equipment like this.
Thanks!
Thank you!
Awesome blast from the past! I used the exact model of machine for my university diploma thesis some 20+ years ago. It had the roughing pump (a diaphragm style pump inside the case though). Brings back memories... Hours and hours of disassembling and cleaning the etching gun, even the tiniest metal flake could short out the HV.
Did he just rickroll us at the atomic scale?
was looking for this comment. I thought the same.
Yes. Yes he did.
@@darth_dan8886funnily enough I was looking for this exact reply
Rick will never give you up. Nor will he let you down.
I am not sure. But all these extremely tiny things make me feel very good about myself.
The thing I absolutely love about this incredibly underrated channel is that I learn so so much about things I wasn't even aware existed. And even for things that aren't even covered but merely mentioned, allowing me to delve into another subject on the internet.
Thank you so much for what you do. You are a treasure.
I remember using these all the time during my doctorate program. I took so many cross sections of through-silicon-vias (TSVs) and surface micro-bumps, testing ways to stick chips together. I also remember using these machines to place in some "bodge wires" and fix up some very tiny pads (even sometimes those little bumps themselves) on prototype dies. Fascinating machines and incredibly powerful tools in the semiconductor world, but I've very glad my work is all computational now, as these things take forever to go from step to step compared to logic and signal simulations I can just let run.
Never a dull video, it's awesome knowing I'll learn something super cool when you post! I wonder how feasible making a motion system for it would be, maybe nab the JWST flexture mechanism?
It has definitely crossed my mind! Would be nice to replace the existing sample stage (since it's missing parts already), so might be neat to replace it with a little XY stage
Love how you explain. Complex topics but very easy to understand.
You have two main knobs to control etch rate in different materials:
* Incident Angle: Metals etch faster with a normal, or head-on angle. Polyimide or photoresist etch fastest at about 60°.
* Relative Mass: Matching the mass of your ion to the material to be etched can change the selectivity. For example, choosing a high mass noble gas could increase the etch rate on your tungsten while decreasing the rate on aluminum.
I have to compliment your atom-on-atom model of the interaction during etch, it was beautiful. One thing though: regardless of incident angle the ejected atoms tend to leave normal to the surface, with a population distribution that falls off with the cosine of the angle away from normal. There is a small population tail opposite the incident angle of the beam though. This is because the momentum is transferred into the surface and the subsurface atoms reflect it back to the surface.
makes sense if you think of it, like a captive poolball, there's really only one way for the ball/atom to go, and the remaining energy is dissipated through the structure as heat.
You should never ever attempt to run a turbomolecular pump in air. These devices are designed for removing most of the remaining particles in a fine vacuum to achieve an (ultra) high vacuum and turn at ultra high RPMs. Running them in air (or any other relatively dense gas) will easily overwhelm the mechanism and crash the whole thing.
Also, Argon molecules don’t exist - as a noble gas, Argon exists only as single atoms ;).
But don’t get me wrong, this was a great and very informative video!
Making Argon fluorohydride out of spite...
Work on some turbopumps, and you find that they only ever run at a few thousand RPM in air. They stay cold. The air-drag prevents their speed from rising (at least it does in the 4in types, TPH-240 etc.)
Problems do arise if they're at normal operating speed, and you accidentally vent your chamber to ambient pressure. That can give you destructive disassembly, and that's why turbo pumps are always bolted to the chamber (or bolted to the roughing pump cabinet.)
Yet again you show me one of the cooler things I have seen in awhile. (The last was that stop motion animation using the electron microscope.) This really is a neat bit of kit.
Would love to see some detailed videos of the problems and fixes used to get it up and running.
Yeah in retrospect I should have filmed some of that. Was just deep in debugging mode and didn't think about it. A lot of the issues ended up being related to the vacuum gauge (it was _really_ dirty and needed cleaning). The reported vacuum level would sometimes fluctuate wildly, which would confuse the machine and think the airlock mechanism had triggered. That had all kinds of effects like turning off the HV supply, messing with the turbo, actuating the airlock vent, etc.
The rough vac pump needs a new diaphragm, so I just replaced it with my other pump for now. Some of the needle valves needed cleaning, and the ion guns needed cleaning too (they get really finicky once material starts to build up, especially insulators). And I think the bearings in my turbo are dieing, but that's a problem for a different day :)
@@BreakingTaps I totally get that filming everything while you're trying to think and troubleshoot is probably kinda annoying. However, I would definitely have loved to see some more "behind the scenes", even if it's just filmed with a lower quality camera (which could perhaps make it less of a nuisance for you).
--- rambling continues ---
While the results are really cool to see, I'm almost more interested in the process. For example, I have a Pirani gauge that's behaving kinda weirdly, and was considering trying to clean/fix it, although I'm not sure if that's even possible - most sources just seem to say that you should be real careful with them, and that's about it (i.e. probably impossible to fix/clean). I'm guessing the vacuum gauge you're referring to is a different one since you go down to ⁓10e-5 Torr, so it probably wouldn't have mattered, but it's just an example of the kind of small things that can be really useful to some people. Sadly that level of detail probably doesn't attract quite as many views, though.
this is super cool, I've used these tools to design transducer biosensors but we referred to them as plasma deposition sputtering machines. Applying atomic coatings of gold in specific ways. Really incredible to see electron microscopy of it though!
We used to have an ion mill for making 3d models of geologic samples for oil and gas reservoir characterization. Basically it would mill down a layer of material, do a scan with the microprobe, then rinse and repeat. Stacking all the scanned layers together got you a pretty decent 3d model of the sample.
8:45 you never fail to rickroll us in a microscopic level
The info is awesome, the ion mill is neat, but the animations are incredible! They make the subject matter so much more understandable.
Thanks for all you do!
Thanks! Been teaching myself Blender lately, glad the animations helped convey the information better!
@@BreakingTapsI’ve been ‘teaching myself’ Blender for a while. My stuff is not like this. Salute!
This is really cool and something I didn't know I needed to see. Thanks for this great breakdown of a subject I never knew existed.
DIB operator for 11 years here. We use the FIB for TEM microscopy. Thanks for bringing what I do for a job to light!
Those scratches at around 9:30 can be avoided with good mechanical polishing practices, it does not need ion milling... Struers OP-S colloidal silica with the appropriate polishing cloth (MD-Nap or MD-chem) can easily give you the desired results.
Ion milling, or more precisely, focused ion beam (FIB) milling can also give more. For example, you can dig out small lamellae for TEM investigations. I used to make them, they were typically 10x20 um large and approximately 100 nm thin at the end of the procedure. The thinning was also done by the FIB, it was a very gentle (and time-consuming) polishing. Also, it is a great method to increase the "resolution" for element analysis (EDS/WDS) in materials. One can dig a cross-section of interest with the FIB, then can dig a trench a few micrometres behind the cross-section. This effectively decreases the volume where the X-ray photons come from, thus the analysis will be less "noisy". Oh, yes, the FIB I used was using gallium for milling and then I could also use it for deposition, but then it was either carbon or tungsten.
Man the visualizations are amazing! so cool! Production values going through the roof.
I really enjoy working on black boxes. A couple years ago I got a helium leak detector from the late 70/early 80's working, and now I am working on a home project to get a HPLC from 1997 up and running. The ion mill sounds like a lot of fun.
I've been amazed by what you accomplish in this channel. Wheter with a team or by yourself, it is amazing to see how one's effort combined with the wide amount of information can lead to something that would require a whole research group. Congrats!
*ONE small* thing to add:
Diamond etching/polishing has worked in your case because the diamond particles you bought were not of a high grade purity and crystalline uniformity. In the latter case it would take way, way longer before you could see any noticeable result. To speed it up, you might need a much more powerful/plentiful ion guns.
Awesome video. I've ben exploring sputtering osmium targets and trying to grow crystalline samples in a quartz furnace. Thanks for the tip about the analog controller. I was able to use the old thermal couple it improved my results by several factors. Extreme control over the temperature has solved the growth rate and size. Thank you again 👍
If you scale this concept up just a little bit you get Quasar jets :D
They can very gently etch galaxies out of existence.
0:53 Stop it. Leave that poor turbo alone.
I had a summer internship working with one of these Gatan PECS system. I used it as a polishing system for EBSD samples. I was using it at very low currents. It kind of works once you get the recipe right for your material system. Thanks for the video!
Wow, this is insanely cool! (Fantastic vid as always too, the animations were great!)
I hadn’t been aware of ion milling before, nano-polishing optics for final figure correction seems like it would be an orders-of-magnitude improvement over conventional mechanical polishing.
I toured a Panasonic lens factory a number of years ago, and saw them hand polishing(!) the tungsten-alloy molds used to make aspheric lenses. The aspheric profile of the mold is formed with a single-point diamond on an ultra-precision lathe. These are quite accurate, but the problem is the diamond tool leaves behind a nanometers-deep spiral groove that can result in ugly “onion-ring” bokeh in the molded lenses. (Bokeh is the term for how out-of-fossil objects are rendered by a lens. Onion ring bokeh makes the big soft background blobs from out of focus background lights in a scene literally look like slices of onions, it’s very ugly and distracting.)
They fixed this by *hand polishing* the molds. A worker would wrap a cloth impregnated with ultra -fine diamond abrasive around their fingertip and very gently rub the surface of the tungsten blank to polish away the grooves. They had a high resolution surface profilometer that they used to check their work, taking many passes on different parts of the blank to both remove the grooves and maintain the aspheric profile. It was incredible that they could do this manually to a precision of 10s of nanometers, and at the time it was a trade secret of Panasonic’s. A couple of years later it became standard industry practice.
This seems like a perfect application of Ion Milling, I wonder if that’s how it’s done now? The next time I am talking to a Panasonic optical engineer I will ask him.
A quick question: What’s the schmutz on the unmilled surface of the diamond on the left side of the frame at about 10:44 in the video? Is that just surface dirt or is the diamond itself that irregular due to poor polishing?
What a great toy! (It a,so strikes me as an incredibly cheap way to get a high-vacuum system driven by a turbo pump 👍😁)
For the rough area at 10:44, at the far left of the frame that’s what random carbon gunk (think oils, random grime) typically looks like in an SEM image. Much closer the etch interface, there may be some roughening due to redeposition of sputtered atoms, or may be roughening in a region which received a low flux of ions near the edge of the main beam.
@@MrPatrick1207 Great, thanks for the explanation!
This is one of the coolest things i’ve seen. Thank you for this video!!
This video was incredibly well done and brilliantly articulated. I’m not an expert in any of what is being discussed but, I at no point felt overwhelmed by the information being discussed.
I was prepared to watch a video with a bunch of cuts of any material and what I got was a guy talking about cutting and then some 100 microscope zooms onto some random stuff that I didnt care about at all.
Keep up the good work 🙂
I work on and teach ion implanter theory for the semiconductor industry and one thing to take into consideration is the process gas used (hydrogen or helium are the most dangerous) can cause x-ray, gamma and neutron radiation when interacting with certain materials like boron in graphite. I doubt the extraction voltage is anywhere near the levels that can cause radiation but it is still possible. When talking about angular etching, this is also applied on silicon wafers during implant. Depending on the material composition at the atomic level we will twist and rotate the wafer to help mitigate what we call channeling where ions are driven deeper in between the crystal lattice. And yes, the nitrogen layer could very possibly be a titanium nitride, tantalum nitride or any other combination. These are typically used as barrier or glue layers to help prevent the attraction or repellent of certain materials based on their interaction with one another.
That is an insanely cool machine. Can’t wait to see what you do with it in the future
Even as an Electrical Engineer (currently doing my master's degree) specializing in Semiconductors I'm very impressed by your abilities and the accuracy of the presented content. Nice job and fun to watch!
The fact that you were able to diagnose this and get it working correctly is probably just as cool as the machine itself.
The cross sections and animations were amazing! Great work, really helped tell the story of what was going on.
Humanity has created such amazing tools. Not just this ion mill but also the microchips we tend to take for granted. Precision engineering doesn't begin to describe these marvels. It's incredible that we all carry them around in our pockets.
If you’re super unlucky, then when you set your alarm to 8:45, you go to the size of atomic level at random TV pops up in front of you and shows rickroll dance
It's incredible how those etched microchips looked like alien city-scapes. I could imagine some kind Giger-esque figures coming and going along the "streets" or in and out of the "buildings". Honestly, I could watch those close up pictures/videos for hours.
This has got to be one of the most INTERESTING videos I've ever seen.
If you put the sample at a very shallow angle to the beam, you can do very fine polishing to reveal crystal sturctures, nano-porous features, etc. Pretty cool technology!
seeing you try to turn on the molecular turbopump hurt me inside, even though it's already broken it feels so wrong to do
You keep making me want new fancy toys that in reality I have no use for but like how could I not want something as cool as an ion mill?
This is what I wish more people were doing as their hobby. So much potential!
lemme just grab some ion mill on some nearby hobby store
I just etched my first diamonds! Time to pick up some more argon canisters 🎉
This is how we make nano technology right this is top down method
I (and two other engineers) built a two axis ion milling machine in 1995 for computer controlled figuring of optics for semiconductor production. I did the software and process development for both metrology and figuring. Some optical glasses are very heat sensitive, so it was necessary to limit beam energy. Also, maintaining a constant ion beam shape and current over many hours was quite challenging.
Oh wow, super cool! Yeah I can imagine making the process reliable and repeatible is really challenging. My machine is very fiddly and easy to go from a beam that is over-etching to one that extinguishes itself. I can't imagine the engineering needed to make the system work reliably.
Really neat project, especially in the 90's!
@@BreakingTaps You've got to maintain a good vacuum with no contaminants. Filament burns out quickly otherwise. I used a 4 variable partial factorial experimental design to get the 2 electrode currents and 2 argon flow rates to optimize the stability and gaussian shape of the beam. There were trade-offs between maximum removal rate and shape/stability. The latter is more important. The better the beam matches the model, the faster the part will converge to the desired shape. Oh yeah, pitch polished glass has different surface layer characteristics for a few 10's of nanometers than the underlying bulk material. So the removal rate on the first run of a pitch polished surface tended to be low. So you needed to be careful as the removal rate often increased after the surface layer was removed. Even so, removal rate was hard to predict, and had to be measured in process on each workpiece. We needed to hit surface shape uncertainty around 2 nm rms.
Whenever I see setups like this, I wonder if you have a vacuum buffer, or if that's even a thing. My idea is to have a tank several times larger than the test chamber. When it's time to run the sample, you can purge the test chamber into the vacuum reserve tank (fun to say) to reduce the gas pressure by the volume ratio of the two spaces. Then you'd be able to run a turbo much sooner, or do 90% of the pumping in the first couple of seconds. A separate pump of even mediocre grade can prime the tank again, while the main system runs on it's own; it doesn't even affect run times. You could even pipe it out to multiple locations, with check valves for sudden pressure failures. Cheap video idea, but more runs per day sounds better too.
I worked at Intersil, they primarily used acid to etch the wafers, but they did have ion and a Yag lazer
Where was this channel all my life!!!!!!? I felt transported for a minute. Thank you for this amazing content!
I am equally - or more - interested in a video about how you fixed all the issues it had. How did you get the turbo pump running?
TBH I'm still not entirely sure what was wrong with the turbo. A lot of issues cleared up once I cleaned the vacuum gauge... I suspect it was giving erratic readings and really confusing the simple state machine that runs the machine. Occasionally the pressure gauge would swing wildly, and then the airlock mechanism would actuate which would cause an actual pressure change, etc. So I'm thinking the turbo might have been instructed to turn off because it thought the machine was in a bad state or something.
I think it was also overheating a little, since the cooling fan had some bad bearings. Once those were fixed it seemed happier too.
Amazing video as always! Haha at 4:44 two particles orbit each other :D
Ha, I made so many samples using this Gatan Ion miller in the grad school. Good old days. Very innovative design. Used to clean those guns every 2-3 days.
The cutaway animation is top shelf editing! Strong work!
A+ clear informative script writing, my respect for that.
Your microscopy is incredible
I used to work in a lab where we prepared samples of films used inside batteries with ion beam etching. For this we made super high aspect ratio cross sections of that film, up to 200:1 so they could be studied in an transmission SEM. A nice trick was that the etching could also be done inside the SEM, which is great news, because it was near impossible to take the samples out of the SEM without them blowing away at the lightest breeze because they were so tiny.
Oh wow, that's a huge aspect ratio!
If someone showed me videos like these when I was in highschool, I am confident I would have picked a different career path in life.
00:50 turbo molecular pumps don’t work unless there is a roughing vacuum in the chamber, your turbo pump controller won’t let your turbo pump’s blades to rotate if you try to power it up at the atmospheric pressure.
This machine has a "dumb" turbo controller and will happily spin it up to max RPM (or at least try, and burn out the motor in the process if you let it) 🙂
This is super interesting and neat to see. But to be honest, the part I'm most curious about is HOW they were developed. Like for example, the Magnetron... How do you discover that if you shoot electrons in a single direction, get them to start spiraling, and put them next to specifically sized cavities, electric fields will start to oscillate at a desired frequency and emit EM waves of that frequency?
Witchcraft.
man, you really blow minds every time i watch you! how is this even possible?
damn damn damn, thanks for sharing
It's very tempting to try to put my hand in there, or is that just me?
amazing that you got those chips, it really allows to really demonstrate
I thought that you weren't supposed to run turbomolecular pumps in atmosphere, the pressure should be lowered with the roughing pump first to prevent damage.
We have huge sputtering coaters at work and the engineers talk like this all the time. We also have an electron scanning microscope which performs miracles often. I've been getting some engineering training on the coaters lately so I can be some help during problem times and take on some improvement projects. I looked down the site port the other day and saw that beautiful plasma, mesmerizing!
This is awesome. Isn’t this very similar to the ion thrusters used in satellites for station keeping?
Yep! They are optimized slightly differently (i.e. no need for a focused beam on a spacecraft) but fundamentally same idea! This particular gun is a very close cousin to the very common hall effect thrusters used on a lot of satellites.
please cover more etching processes (i would love to see drie etching on this channel,seems like a very criptic process to me )
Wow this is insane!! Ive never seen a more beautiful cross section of a chip before!
At work I had a lot of options from 'wrecking Ball' Caesium Ion Sources to very energetic Oxygen Ion sources (which ate filaments !) down to very light Ion's. We had a FAB process (Fast Atom Bombardment) where we set up the Ion beam focus and all that good stuff then passed it through a charge exchange cell (more gas) and you end up with a neutral beam. This was great as one of my favourite studies was 'Depth profiling using Ion Milling to dig the hole, fascinating when using complementary techniques of analysis (SIMS or ESCA) and working your way through a piece of magnetic tape from a video cassette looking at the best bit, and that was the 'Interfaces' of the various layers. This is a stunning video so Kudos there ! and there aren't enough channels for us ' Nano Nerds' anyway !!...cheers.
If you want to etch diamond CBN or anything else that is very hard, add a few percent of either oxygen or hydrogen. The texturixing etch followed by ion implantation is an important step for solar cell manufacture as it greatly increases the surface area of the cell. ❤
Sometimes I think there is a guy working at youtube specifically selecting and recommending the best videos and channels for my personal benefit. Great video.
The tungsten micro-masks remind me of the sandstone pillars (hoodoos) in the American southwest. A tall pillar of soft rock capped by a hard stone, molded by the rain.
I managed to drill a hole in 1mm glass by similar method. After repeating a few times, the tiny pore actually became visible to human eyes.
PS, with a focused beam, the micro-hole drilling is used for making thin samples for TEM microscopes. Scan the FIB ion-beam to drill two adjacent square pockets in your solid sample, with thin walls or "lamella" between. Break it out with a micromanipulator. It's not nano-sculpture, it's just sample-prep.
Heh, TEM microscope. FIB beam, LCD display, HIV virus, PIN number ...that's the RAS syndrome, meaning, redundant acronym syndrome syndrome.
At 8:00, how do you manage to get distinct per-atom-type views? Thank you for the amazing video
My scanning electron microscope has an detector which can identify the energy of x-rays, and uses a technique called Energy-dispersive X-ray spectroscopy (EDS / EDX). If you hit an element with a highly energetic electron, it will sometimes emit an x-ray. And the energy of that x-ray depends on the atomic properties, so each element has it's own "signature" of x-rays that are emitted
The EDS works by slowly scanning a high energy electron beam across the sample and collecting the x-rays that are emitted. It then looks at each pixel and determines what mixture of elements are present based on the x-ray signatures at that spot.
Not sure of the type or manufacturer of turbopump but I would refer to the manual - you may be causing overheating or mechanical stress if you ran no load in atmosphere
Your content is amazing and I love that you endorse Rust. Good luck with all your amazing projects, I am sure it will be part of the inspiration for my own.
I can't help but keep thinking about what would happen if you accidentally got hit by one of those ion beams. Does not seem like a good time.
I suppose it's a bit like an ionising laser, but is a lot more precise, similar to use obsidian for surgical instruments, instead of traditional steel scalpels.
Neat machine. Now I want one. Tho' watching you run the TM pump open to full atmosphere did give me a slight case of the woogies...
6:53 Thank you. The photos are deeply satisfying
4:28 LOL 2 of the simulated atoms decided to orbit each other, marvelous.
combine that with crt, at nano level, you have both nano horizontal and vertical milling-etch accuracy. metal copper heat conduction base plate.
you could also use a soft electron/ion beam to cure an etch mask, so you dont destroy your main high precision etch mask with the electrons/ions, you know the spin sludge on the silicon wafers, then remove any uncured parts of the temporary cured mask, then do the actual hard electron/ion etching, ie to keep the original mask intact, to support multiple copies of the same pattern reliably. industrial processes rock. not sketchy at all.
Some of the really fancy machines have active cooling too. Water cooled copper blocks, or even liquid nitrogen circulation loops.
Hi Breaking Taps,
Super nice and interesting video.
Just a simple question-idea.
I'm a (bio) chemical engineer specialized in organic chemistry, but I do love technology.
Into chemistry, it is wel known that gases average (quadratic) speed depends on atomic mass; so hydrogen diatomic gas (H2) moves faster than Helium, than dichlorine (Cl2) or than SF4; and speed depends also on heat (molecular agitation, and free move traject in Brownian agitation), just like pressure (number of molecular shocks on the wall's surface).
So here is my question:
You used Argon (MW 39,95); but what if you used Helium (MW 4,00) or Xenon (MW 131,29); whould that mean that those inert gases would be also accelerated to atomic blast; but Helium would be accelerated roughly 10 times kinetically faster (but with different impact force due to F= mass*(impact deceleration)) and Xenon about 5 times slower but much eavier thus providing very interesting different abrasing results than Argon.
Regards,
PHZ
(PHILOU Zrealone from the Science Madness forum)
Are these circular marks on the etched surface (especially visible on the Diamond) the impact craters of single argon atoms? I find that somehow hard to imagine, they look pretty large.
I think that's a mix of crystal orientation and local topography. Different crystal orientations of a material will etch at different rates, so big hunk of diamond for example will be a mixture of different "grains" (unless it's monocrystalline diamond). And some of those grains will etch faster, leading to a pit.
And local topography can affect it too. If there is an existing pit, that'll tend to grow faster than a flat area (more surface area to get etched). Or if one region is facing the beam a bit more, it'll etch faster. Ditto to impurities that might etch faster.
So yeah, it's a combination of stuff, but definitely not individual impact craters. Too large as you said! 👍
this man has tools and knowledge i didnt think would be possible to find outside labs, wow, amazing video
Looking forward towards that RIE video.
Are you going to use the same machine for RIE, or a different one?
You can do the same thing with Sound, the Egyptians did it. 💨
This is one of those concepts you might come up with independently in your college years, and then get stoked when you find out it's already a thing.
For some reason, when I was watching this I was thinking "why haven't I seen this in a James Bond movie yet?" Imagine what this would do as a weapon.
I wonder if you could etch a knifes edge, and how sharp you could make it. That would be pretty cool to see.
What were those little "hairs" on the etched area of the diamond at 10:44? I can't see any on the non edge area.
Carbon adhesive goop, just an artifact from imaging 😅 I scanned the top of the diamond, then rotated it to get more of the profile. Apparently the carbon adhesive dot that's used to hold it down left some whiskers of polymer behind after I rotated it. Meant to put a caption on screen about that, but totally forgot!
I'll pin a note about this so others know 👍
Amazing technology. Great work getting the etching machine working again
Tip: Find a linear induction and maglev motor bearing for the turbo motor (I'm assuming vacuum motor). It should last a very long time. Like transistor radios, they should become ubiquitous very shortly.
About 7-11 levels of contrarotating blades (think planetary gears) should bring you to about a 99.987% vacuum. But why stop there? Between metallic printing and 23 contrarotating blades (yes, all, no stationary, all with electromagnetic (gasp!) planetary gears, the entire system has zero contact friction, albeit some loss due to hysteresis, so it should be darn neigh indestructible, right? Pull the vacuum, stop it off, conduct the experiment, then repeat as necessary, ad infinitum.