Silicon Carbide: A Power Electronics Revolution 

Silicon carbide is pretty SiC

Impressively well researched video for a non electronics specialist. You’ve done a far better job than other commentators on the topics. Love your videos.

Until a few months ago, I was a research fellow working on silicon carbide devices. Please allow me to leave some commentary: 1:40 - 4H and 6H are the only polytypes that can be grown as commercially-relevant bulk wafers, but 3C can be grown on silicon! 3C-on-Si is... well, it's not great. In layman's terms, the atomic spacing of 3C-SiC is different to that of Si, meaning 3C-on-Si is *full* of crystal defects. Just to pile it on, SiC fabrication processes can get up to 1600°C, but Si melts at those temperatures, meaning there's key steps you can't do properly to 3C. I am very interested to see if the 3C wafers devised by Francesco La Via and his team - where they start a 3C layer, melt off the Si and grow a new 3C wafer from the starting layer - can reach the crystal quality and practicality required for real devices. 3C has a bandgap that's not as wide as 4H or 6H, but its electron mobility is higher and it might compete with GaN in lower voltage applications. If La Via and his guys can improve their process! 2:00 - 4H has a wider bandgap than 6H and isn't much harder to grow, that's basically why we're using it. 2:08 - Tangent: the same strong atomic bonding that makes SiC hard also makes it a pain in the butt to chemically etch. Acids don't do anything to it and basically the only way to etch it is high-power plasma etching (plasma etching is common, but SiC needs a serious bombardment before any of it goes away) 2:26 - This explanation is generally pretty good. The wide bandgap of SiC means better temperature tolerance (lower intrinsic carrier concentration) and better voltage blocking, but you glossed over the higher frequency thing (and, TBH, I don't blame you). SiC has a higher electron saturation velocity than Si. Effectively, the electron speed limit is higher. *BUT* while the electron saturation velocity is higher than Si, the electron mobility is *much* lower (and don't even get me started on the hole mobility). The speed limit might be higher, but you've replaced your roads with grass fields. While SiC can *match* Si up to ~10MHz, it's beaten tidily by GaN at radio frequencies. 4:10 - While SiC as a semiconductor tolerates heat much better than Si, there's a reason why SiC transistors aren't rated to higher temperatures and it's *super important*: the oxide of the metal-oxide-semiconductor field effect transistor. I'll cover it in detail below... 6:57 - Partially true. Above 6.5kV, we go into the world of thyristors. Which I don't know that much about, other than 'big, scary whole-wafer devices', so I'll stop. 7:32 - This stuff about heat is a bit misleading. Power semiconductor devices *always* need heat management, but once you've put them in a proper box, the environment is usually less important than what thermal management you put in. 8:09 - You kinda turned over two pages at once here, mate. Batteries do not store as much energy as a tank of fuel and getting a battery electric vehicle to travel as far as an internal combustion engine (ICE) one is very difficult. Also, paradoxically, the high efficiency of electric motors means that small inefficiencies in the car's design turn into bigger losses of range. Those pop-out door handles that sit flush to the car while driving don't really make any difference to an ICE car - which is already pissing away ~80% of its energy - but they do genuinely help with an EV. Thus, adding or saving weight translates more directly into range, which is something EV buyers prize highly while they make the adjustment to EVs and their shorter range. 8:18 - Sorry, this is a pretty big error. Also kinda complicated to unpack, but I'll give it a go. Beyond the transistor itself, building a power converter requires passive components. Capacitors and inductors. Transistors switch almost a million times per second and passive components act as energy reservoirs to smooth out voltage and/or current. The faster the switching speed, the less time the passives need to plug the gap for, and the smaller they can be. When it comes to capacitors and, particularly, inductors, a larger capacitance/inductance value means a physically larger and heavier component. Fast-switching SiC MOSFETs (they switch much faster than a Si IGBT of the same voltage/current rating) mean smaller, lighter, cheaper passive components, and this is where the bulk of the efficiency saving comes from (although faster switching normally also means lower losses in the conversion itself, so higher efficiency and less heat generated). 9:27 - Material growth *is* a major limitation of SiC. It's not the only one, and I need to do a full-length diatribe about oxides below... 10:37 - This breakdown of PVT growth is *excellent*, and I just learned a thing or two about it. This explanation makes the process sound a lot cleaner and less messy than it really is: controlling the temperature gradient around the reactor well enough to create a decent SiC ingot with no polytype inclusions is extremely difficult, and I'm not entirely convinced that another ingot growth method isn't going to replace PVT (/hottake). 11:58 - SiC wafers can be laser cut. I don't know about wafering from an ingot, but it's also possible (if a little risky) to cleave the wafer to dice it, like cutting glass. But just laser cut it. OK, I need to talk about oxides, not just because they were the topic of my PhD but also because they're the weakest part of a SiC MOSFET. When making a metal-oxide-semiconductor stack for a silicon transistor, you use the silicon as a ingredient for the oxide. Stick a clean wafer in a hot furnace with oxygen flow and it will slowly oxidise to a very clean, orderly silicon dioxide. When you try to do this with SiC, for a few nanometres you get Si oxidising to SiO2 and C burning off as CO2, but the carbon quickly ends up trapped in the oxide and at the oxide-semiconductor interface. This tanks the performance of the oxide. There are moderately-effective ways of un-tanking the performance - using NO or N2O as the oxidising gas, instead of oxygen - but they're still much worse than for Si devices. The on-state resistance of SiC MOSFETs is limited by the quality of the gate oxide and the MOSFET channel it produces. The maximum temperature is limited by the reliability of the oxide: up to 175°C, the oxide is OK, but above that its lifetime shortens drastically. My pet project during my postdoc (which I've still got a successor working on, which I am super-grateful for) was depositing SiO2 rather than oxidising the Si. You can't trap any carbon if you leave it all in the semiconductor. Instead, you have different problems, like oxygen vacancies in the oxide. I should stop. Thanks for sharing. This video is a good introduction and overview of device technologies that you don't see in popular engineering. Good stuff!

Wonderful! Can you also explain the Galium Nitride (GAN) transistors and how they compare to Silicon Carbide and other power switching devices. GANs are apparently also finding their way into power electronics lately.

John Atanasoff, inventor of the Atanasoff-Berry computer, one of the very early stored program digital electronic computers, talked in a speech at the Computer History Museum about theorizing about building transistors out of silicon carbide as far back as the 1930s. He knew that both galena (lead sulfide) and silicon carbide could serve as a cat's whisker crystal detector in a radio set. When they were improperly adjusted, they would oscillate, and oscillation means gain/amplification. Interesting that silicon carbide semiconductors are now a commercial product. Atanasoff envisioned making them out of what we would call nanowires.

About carbide hardness: tungsten carbide is used in good ballpoint and gel roller pens as the ball. It sees a lot of wear and needs to remain smooth and spherical to apply ink evenly

I took one condensed matter/solid state physics course in college and this video was very digestible, I would say even for people without the physics background.

Another great video. Being an engineer this was very easy to understand, but I think your explanation still bought a lot of easy to understand points to the Lay person. Your walk through the history of the materials and technology is also most important for the younger viewer (I do hope you have many young viewers). Thanks.

You often mention "packaging" which means something different than what most people normally would understand it to be (cardboard boxes and styrofoam). Can you do a video on the meaning of "packaging" throughout the semiconductor industry?

I AM OUT OF CONTROL AND SILICON CARBIDE IS TO BLAME!!!

@7:41 I don't think many people in the world would recognize that! It's the underside of an older Proterra bus. Having worked on them in wintry cities, I can confirm that those are some harsh conditions indeed.

I don’t find many videos out there that dive into details of semiconductors like this. As chip designer I actually learned things from your video. Please, continue the great work you have been doing in this channel.

This is why I Love this channel, I always learn something new about industry with a little dash of humor on the side.

Consistently impressed with how you distill technical topics into their essence, explaining enough detail that a scientist can understand while a layperson can follow along. Another disruptive application of SiC is in electric kilns, nichrome wire barely gets to 1200C, SiC filaments can get up to 1600C. Would be critical for decarbonizing heavy industry like cement and aluminum. One of the issues in this field is also with scale of heater elements.

Thank you for giving me an introduction in this technology as I work for Inverters in the automotive industry. This really was a useful introduction to something everybody speaks of, but nobody dares to really explain

As a college undergrad in 1991 I worked in a university (University of Florida) research lab doing preparation and characterization of Silicon Carbide deposited layers onto various materials. Our method was chemical vapor deposition whereby a graphite holder inside of a quartz tube surround by outside copper coils with cooling water running through them would be subjected to an A/C current. As the magnetic fields changed polarity many times per second the graphite crystal layers would react to the changing magnetic fields and thereby induce heating through the friction associated with the graphite layers "rubbing" against each other. It was so long ago now I don't remember the exact temperature but I do remember the graphite would begin to glow after a short while. The substrate (Alumina if I recall) we planned to deposit the SiC on was placed on the graphite holder during assembly and consequently would also get heated to exceedingly high temps. Once the entire assembly was up to temp I would inject into the reactor a steady flow of Hydrogen (H2) gas bubbled through a silicon tetrachloride solution. The SiCl4 would diffuse into the hydrogen and be transported into the reaction chamber and them a constant stream of methane (CH4) gas was used as the source for carbon in the experiment. The high heat energies would rip apart the molecules and you would then have a gaseous phase of carbon, silicon, chlorine and other elements above the substrate. Some fraction of these materials would react to form Silicon-Carbide (SiC) that gets deposited onto the substrate. The whole purpose of the experiments were to characterize the regime under which you maximized SiC production and minimized other undesired reactions. For that we would have to take the samples to the materials science department on campus where we could use their SEM to check the deposited layers for purity. All of this work went on for years and formed the basis of a PhD thesis for a graduate student I was working with. It was also funded by DARPA principally as a means to identify coatings that could be used in tank engine components to protect them from wear and corrosion. Never did I imagine there would be a use for this material as a semiconductor. Although I have to say it makes sense because the professor who was the PI for all these research projects was a specialist in semiconductor materials.

Finally SiC!!!! .. Im Ph.D student and I'm working with silicon carbide.. Finally a video about that!

A new step in semiconductor tech. Brilliant video, thank you.

well researched and surprisingly interesting as always

Multiple people have mentioned doing a video on GaN, I'd love that too. Another worthwhile topic relates to that graph about growth in the power electronics device use - the insane backlog in getting devices. There a cracks in the supply / demand when it comes to processors and other devices, but the high backlogs on power electronics looks solid.

Another wonderful essay from Jon at Asianometry. I always feel so much wiser after seeing or hearing (sometimes I just listen) to his well choreographed presentations. This wisdom doesn't last long but it's nice while it does ☺. Maybe when I get my silicon-carbide brain implant that will change 🤪

Another masterful episode....Stories such as these, and the one on MEMS bring to light the lesser-known, but equally vital components that are starting to underpin modern lives. Thank you for this episode!

Informative and of high quality as usual. Thanks for sharing!

Very nice summary, and a great starting-point for anyone starting to study SiC!

Great job covering this challenging subject.

Thank you for all of your work, it's well explained and totally understandable.

You're a godsend Jon! You bring up everything I didn't know I wanted to know :D

Another amazing and informative video !!! Thanks Brother !!

Thank you again, I feel as if you have really expanded my knowledge base on this topic. I am very grateful.

Big fan of your videos, I have been following and keeping up closely. I work in the Industry for the major semiconductor tester manufacturer (starts with a T). Would feel honored if you made a video on the concept of semiconductor testing. All manufactured chips need to be tested before use, so its a big part of the industry.

Fantastic video good technical overview of the difficulty of manufacturing these components👍👍🏆

Following you already a long time and was wondering when you do the video about one of the most powerful changes in the industry for high power applications. I am working for an SiC Semiconductor manufacturer and i think you did a great job explaining the technology. Short correction traditional silicon mosfets work up to 100V max.

That was a very clear explanation -- great work!

been away from electronics for awhile and i still understood most of this. great video!

Another very interesting video. Thank you for posting.

this is one of the best channels on youtube, it's got memes, it's got technical information, it's got frequent uploads, its got good production

Your videos are very thorough and well made

I have to say, I particularly enjoyed this episode, the mix of science, applied technology and economics was excellent and well delivered.

I work in the semiconductor industry and we are currently experimenting with improved SiC chemical mechanical polishing methods :)

Thank you for the video

Very nice video! I'd like to add that amorphous SiC also has great potential in developing photonic circuitry due to its high refractive index contrast with silicon dioxide, along with very tunable absorption characteristics. Interesting applications for the telecom industry, as well as some quantum internet and computing applications (due to adhering well to diamond which is popular for single photon emitters).

The meme jokes may be misaligned with your demographic. The 'water succeeds gasoline' joke is perfectly aligned with the same. Good video, had a couple chuckles watching it!

Great work.

Super interesting. Thank you.

Thank you Mr.Bane for ur wisdom

Thanks. great vid.

Superb!! Thanks a lot 🙏🙏 curious about how much time you spent making it

awesome presentation sir

Excellent! I used to work for one of the big utility solar companies. Getting PV string sizes up to 3kV (from 1.5 today) dropped total system cost over 10%. One limiting factor was the silicon transistors in current inverters so this could address that.

Awesome video as usual! 👍 Thank you so much.. Hope you can do a video about Aixtron, very interesting company in this space too!

You are a very knowledgeable guy, thanks for all the great videos

I like how you had fun with this one.

Excellent video as always. Microsemi was acquired by Microchip Technology in 2018

15:10 future applications might crop up ... in the future I felt that so hard because I've said stuff like that out loud so many times. Great video, just trigger my OCD with the last bit there :)

As friend of the channel Bane once said... Love it!!

Great video! I want to see more SiC stories

I really love your videos. The content helped me understand SiC much better. Will it be possible to create video content on Sputtering target coating? IE Ta2O5 - high refractive index paired with low refractive index coating and its applications. Thanks!

I wish you could keep going too bro. do a longer video for those of us that listen religiously.

What suprised me about this is that the video infered Silicon Carbide was resent. But Texas Instruments has been building commercial products out of it for over 10 years. They do make a lot of power electronics out of it but they also make Microcontrollers and CPUs and many other items.

Ended up here from researching my 1st guitar amp, at least I understand a few things a lil better, thanks dude.

Wonderful channel I'm new to it with my research of physics in plasma and hi voltage. Keep up the good work of furthering understand of that world in science Thank you very much

3:32 ". . . become like internet commenters and cannot switch off, becoming useless." Brutal! I love it ROFL.

Always with something interesting... 🙏🙏🙏

Dude you make great content and arent super narcissistic or annoying. Props

Amazing! I was wondering as you talked if these Soviet inventions contributed to the (relative) success of the Venera probes. Nice that you mentioned later that they did indeed.

“I love rocks”…subscribed!

Excellent ep as always! 5:09 SC and Slovakia LOL😂

thats a really nice primer

Thanks!

Perhaps gallium nitride (GaN) power electronics should be covered as well, because it is one of the main competitors to SiC

Great video, could you do a video about GaN?

Would love to see more silicon carbide electronics episodes.

Interesting video as I started making use of the silicon carbide Schottky diodes for Meyer's technology as I learned how it worked and where Meyer went wrong and made many improvements to the technology using silicon carbide chips. I never knew the history behind the chips but just saw them on the market and was amazed at what they could do for this technology. Now the water for fuel technology basically lives again but I have to build it correctly first but I have posted the science behind this technology to put down years of fossil fuel industry propaganda about the technology. When you look around the world you will notice that everything is already powered by hydrogen as all life depends on hydrogen to survive. I went over photosynthesis very closely to see if they had missed anything and it turns out they did. You see they never asked, "How does a plant break the bonds of the water molecules?" Answering that question lead me to the true science behind the water for fuel technology. What I found in my research was Meyer's method basically mimicked the earth's Global Electric Circuit and I suspect that Dr. Dingle's did also. All of these men were brought up in a court of law controlled by the fossil fuel industries money and lost their court cases, wow! big surprise there, huh? Anyway I posted the science behind this technology at the OverUnity site under, "Stanley Meyer Explained." Note it is just the science as learning how to make it work correctly I did not teach, but I had to post it so that I could put down the propaganda surrounding this technology created by those that sell fossil fuels for a living. I'm not really a fan of EV's as I know there simply isn't enough materials to go around to be able to replace ICE cars it's a dead giveaway if you just pay attention to the name of the materials they use to make EV's as they use "Rare Earth Materials," meaning there simply isn't enough to go around as we are talking more that 1.3 billion cars needing to be replaced and that number doesn't include other vehicles such as ships, farm equipment, warehouse equipment, and all types of planes of which the current technology doesn't have the power density to power right now. Thus the true solution is to switch the source of the hydrogen we need away from fossil fuels to just using plain ordinary water.

"I love rocks." Jesus Christ, they're MINERALS!

Love your videos about the modern electrical components! Funny memetics too 👌 Any intention to talk about Gallium-Nitride (GaN) rectifiers? They kinda took the charger market by storm in my opinion (not that I closely followed the space), and saw in your graph that their production cost matches Silicon based electronic components. Would love to hear your research about the topic! Scrolling through the comments I'm not the only one with this question. I didn't intend to join some kind of gang-up. x)

5:45 What a beautiful sine wave :D

Your voice is so soothing...☺️

Great vid on WBG semiconductors! Would you consider doing a video on GaN power devices (if you haven’t already)?

I make the wafers in the lab at Wolfspeed. Very easy to understand and build.

Amazing!

great vid

You like rocks and the Loki series? You are just full of hot takes! Very bold!

Gem of a channel.

You forgot one big thing. Heat radiates with the 4th power, so a chip that can get twice as hot, can radiate 16× the power. 150V vs 900V is a 6× increase. Which means a 1300× fold increase in heat dissipation, but power rises with the square, for a net of H_dis = V²

great Video. Please also make videos for GaN.

one more great video.

Hey it’s my car! Another excellent video.

Your subtle stab at internet commenters made me laugh 😂. And yet here I am commenting again! Great video! Just joined your newsletter too! Love all your hard work 🥰

Hey, what is the source for the charts near the end (e.g. Si vs SiC vs GaN inverter cost breakdown)? Thanks and great video!

Looking forward to silicon carbide based mosfet use in other power technology in Battery BMS units and Solar Inverters.

Great video! Can you follow up with a greater discussion on the players within the SiC supply chain? Everything from furnace suppliers, through wafer makers, device manufacturers, and inverter suppliers. Furthermore, I know China is aggressively moving into SiC and GaN. I would love to hear your assessment of the key players there too.

3:30 major shade being thrown

In 6:08 you must indicate the sign for alternating current in the input. Not like here in the picture a plus and a minus.

Tenet right off the top! My favourite movie!

Defective (maybe, maybe not) boron carbide chest plates for furnace lines are on ebay. Carbide sandpaper for metal and flint or ruby for wood or you'll be sorry. Al ox is fine for rough work.

youtube algorithms making sure i watch everyone of these videos

3:30 I should switch off, but instead I'm here commenting that I feel personally attacked

Very informative video.. A follow up with GaN power electronics? 🤔

Request to create an article on "electronic packaging"

A video comparing SiC to GaN in power electronics applications would be cool