It's surreal to see things that I remember as proof of concept research papers start to enter mainstream production.

this channel is always a source and never a drain

My Father used to work for GEC when they were making the first germanium transistors. He said they would use car headlamps as a heat source to attach the legs to the Germanium wafer. He kept a load of the prototypes that had exceptionally high gain.......I tested some the other day and they are still good 69 years later.

You know you've done a good job with your videos when I saw the title and actually knew what it meant, and was actually excited 😂

I have learned more about fab processes from your channel than I did getting an electrical engineering degree.

I like how you uses pauses that gives the viewer time to digest the heard and think about it.

Also know as: damn-thats-a-long-name-FET

You just have to appreciate all the scientific research done in decades past to make these advances possible only now. Also, I think an increase in competition in this space will further the progress made, and also reduce the risk of losing production capacity due to various outside factors. Semiconductors are vital to modern life and society.

I am in an Automotive Tool group on social media and they were questioning Taiwan tool quality... I can't believe I had to remind them how the small country makes the highest precision instruments the world has ever known. Arguably the greatest human endeavors come out of Taiwan, akin to the space program and CERN.

I really wonder why I subscribed this channel with all this in depth knowledge I don't have any use for... But it's fascinating!

the GAA design offers great advantages for scaling down semiconductors. The normal problems we experience when scaling down lower and lower is reduced because of the enhanced electrostatics (reduced leakage currents and improved switching speed and energy efficiency). I can't wait to see the next gen semiconductors using this tech. It is going to be crazy!

Jon, Thanks for the update. Was wondering where GAA was at from a production perspective after you mentioning it in prior reports.

Minor correction; at 6:05 you talk about the effects of dielectric permittivity on gate function, and while obviously higher dielectric materials produce a higher capacitance, the electric fields within the substructure are actually *reduced* as an effect of the polarization, which can be essentially described as the realignment of electric charges inside the dielectric that cancels out the external field.

2nm ! Damn, I got my EE degree less than a year before the 1um barrier was broken, back in 1985.

i am 22 and seriously thinking about studying engineering at this age, thanks to you. i am quite speechless with this content, thanks.

What do transistors and professional athletes have in common? They both get their strengths from doping

MOM MOM ASIANOMETREY MADE ANOTHER TRANSISTOR VIDEO, GRAB THE POPCORN

I remember back in 1968 reading a Scientific American article on how to make a transistor by spraying various chemicals on a piece of glass on a hot plate. Things have evolved!

Lol, that sudden picture of the IMEC building. My grandma lives across the street from it.

I remember when MOS/FET’s were new. I was an electronics technician for many years and they were somewhat different to troubleshoot but very reliable.

we’ve had MOSFET and now we will have GAAT 😂

9:35 minor correction. Epitaxy is not a deposition technique, it is the process of growing a single-crystal film on top of a different material with similar lattice constants. Epitaxy can be achieved with different deposition techniques such as evaporation or sputtering.

dude, I cannot imagine your level of energy when you post so many great docs about tech and the economics and/or politics of tech, so often, and with such great ease. congrats.

Grok's custom ASICs are using 14nm established process node and demolishing GPU based AI accelerators - these new transistor designs aren't needed for AI acceleration as there's lots more headroom in transitioning to custom ASIC designs with integrated memory for example, than what can be squeezed out of an evolutionary step in transistor design.

For the basic drawing of the transistor some sort of PowerPoint Animation might have helped to better visualise the gate getting thinner, source/drain pool becoming shallower/deeper, etc. but regardless loved the video. Thank you :)

Can't believe they didn't call DIBL DrIBL, given what it meant

TSMC Backplane Power Delivery would act as a flavour than a specific node, and there would be backport possibility for other node.

I’d be very interested in seeing a graphical explanation of how these structures are constructed. You had part of an explanation but then it never finished. Either way, your videos are incredible resources!

A FET is basically a solid state version of a vacuum tube. Both use an electric field to control the flow of electrons.

Both lucid and precise, gotta love it!

A transistor is not just a switch (on/off). it can also behave like a variable resistor (linear operation). Even if in the field of Digital Electronics, it is always operated (biased) to perform as an on/off switch, the device can also be operated on its linear response characteristics to perform as an amplifier in the analog world. On the input and output sides of a digital circuit we still use transistors as linear devices. After the junction voltage is overcome, there is a nice linear response of changes in current to voltage (smooth changes in input current produces proportional changes of output voltage), before the transistor goes into saturation (completely On). If someone ever invented a true 'digital relay', transistors would become obsolete.

5:11 There probably was always a parasitic drain from source to drain even in larger nodes. They just happened to be outside the realm of measurement or significant meaning. But as you close the gap, the electromagnetic field will naturally jump past. This seems like it would be kind of obvious.

Thank you. Your explanation was the lightbulb moment for me. I've heard and read a multitude of explanations of goafet transistors and it didn't quite click for me. Thank you for breaking it down so eloquently.

I work as an analyst and your channel is truly one of the rich resources for my learning. You're one of a kind and your videos will forever be a treasure to anyone who wants to learn about these topics. Thanks a lot man!

how many gates in gaafet transistor with backside power delivery.

The amazing part is that they are doing this at the near atomic level. I was thinking that the next level is to use the photon combined with wavelength and polarization to do switching thereby eliminating EMF issues related to latency and wasted heat energy.

🎯 Key Takeaways for quick navigation: 00:41 *🔄 Next-gen transistors.* 03:38 *⚡ Short Channel Effects.* 07:33 *🔄 Gate-All-Around (GAA) transistors.* 11:27 *🌐 GAA vs. FinFET power draw.* 13:52 *⚙️ Intel's Ribbon FET.* 14:32 *🌐 GAA's industry impact.* 15:00 *🔄 Future transistor designs.* 15:42 *🚀 Looking ahead to N2.* Made with HARPA AI

How on earth do you produce highly technical and qualitive videos so regularly? Do you have a team helping you? Always interesting and informative.

What is this channel I randomly stumbled across? This video was extremely well done. Love it, will definitely check out other videos on the channel

As always, amazed by the quality and amount of information stacked in this video! Very informative!

Thank you for making this extraordinarily clear and interesting video on a subject I wouldn’t have otherwise stuck with, let alone begin to understand. What I found most exciting about all of this is that this work at the atomic level reveals a nexus chemistry and physics, but also origami! As you presented each new photographic or diagrammatic depiction of architecture evolutions from FinFET to GaaFET, I began to imagine something like the Forksheet. Hello origami! Then, (whoop!) there it was! So what theoretically lies beyond 3d transistors? When you mentioned techniques for 3D chip making borrowed from MEMS, it made me think about how switching photons vs electrons changes things. So how far are we from building photonic processors of similar density/efficiency? (Begging forgiveness for my ignorance and possible/likely misuse of terms referenced and engineering concepts please! I’m a technology sales rep and avocational musician, not a theoretical physicist or electrical engineer!)

Semiconductors aren’t called that because they only conduct some of the time… they are called that because they have higher conductivity than an insulator but lower than a conductor

4:31 sounds like Officer Dibble from the “Top Cat” TV cartoon ;)

Excellent presentation. I appreciate the background and detailed descriptions of competing methodology, and as an investor, the anticipated timeline of new methods. Great stuff. Thanks.

I work for imec on CFET. It's nice helping to shape the future🙂

This is great all around

2:16 "names are surprisingly descriptive in semiconductor land" That's something that bugged me in Physics, there's so many effects named after the discoverer like "Hall Effect", "Nyquist noise" and so on.

We are so lucky to have this channel. Thank You 🙏

Loved the video, and I greatly appreciate your continuing education of computer science, break-throughs, and history. ❤

5:35 “kind of like loud talk from your neighbours in a bar messing with your attempts to say, sweet, romantic things to Siri” 🤣🤣🤣

Outstanding as ever - clear, concise and informative.

Many types of transistors. FET as they were describing. Standard, MOS FET’s for power applications. N Channel P Channel FET’s low Power Application.

9:28 This looks pretty insane.

Thank you for explaining in an intelligent, thorough and graspable form…I actually understood😅

Is GAA/MBC the kind of thing that can be back-ported from EUV to DUV to improve density/power/performance of older nodes?

10:02, Aspect ratio is width/hight, hence it’s low aspect ratio. You have changed the definition to justify your take high aspect ratio with more hight than width.

abour Ξ mos for the letter "Xi", it is pronounced like the x in wax, not "see" or "zee"

I LEARNED WHAT A TRANSISTOR IS

Nice work. You successfully made this knowledge digestible to someone in rural Tennessee. Whomever writes these has a talent for explaining things.

I like how the relevance of this really pushes everything back into data centers. Welcome back to the age of the mainframe and the thin client. Your rectangle is a brick without a half ton space heater sitting in a warehouse.

amazing stuff.. its like making a nano casting, sacrificial space to hold up a shape. from linear, to lateral to 3d.. and it is not even farctal geometry. It all has a purpose/destination.

Any sufficiently advanced technology is indistinguishable from magic

XI in Greek sounds like Kai. not shi. we use it in electrodynamics as relative permittivity

2:07 Hey, that's Richmond Park! Jon, if you ever visit London, I'll take you to see that gate.

All semi foundries promised this 5 years ago, then it was “ready” 2 years ago, then “really ready this time” 12 months ago, and now completely abandoned in favour of backside power delivery. What happened, Asian deer man??

Fascinating - seems like we're approaching limits of scale at some point....this is where someone develops a new material or a new paradigm to take digital manipulation to the next level....optics? Magnetohydrodynamics? Some new graphene variant? Can't wait to find out...

I've been out of the semiconductor game for a long time. Does anyone have the figures of merit for these transistors?

I've only seen a few of your videos but each time a third of the way you get through it you get silly and I love it EDIT: not silly as in old-school @ThioJoe but silly as in just a little bit fun with the delivery

4:40 "Like a rabbit" is hilarious. The pause afterwards is amazing.

I have no idea how we every figured out how to DO anything with these developments..? It's basically magic

Interestingly (to me anyway) the FET (Field Effect Transistor) is what should have come before the type of transistor which came out first. The idea of the transistor was to replace vacuum tubes and vacuum tubes work on the same general principle as FETs. A static field applied to a screen grid (just like the grid on a screen door) controlling a much larger flow of electrons (emitter to plate). But semiconductor tech wasn't advanced enough to make that readily possible so they went with current control rather than voltage control. The very first "proof of concept" transistor was constructed with a liquid semiconductor. Current control, however, is costly as to wasted power and heat was always a problem. MOSFETs (And better still, C-MOS) can be made such that they only really draw any power when they are switching states. The faster they do the greater the power draw and the greater the heating, which is a big problem today with the newer vertical stacking techniques.

Man I have been waiting so long for the GAAfet to be consumer viable! very hyped

Terminator Skynet in download 95% complete...

While listening to this i had a stupid idea. How about consturcting a cube of transistors instead of a sheet, and the way you would reach transistors inside the cube is by deploying 2 currents, but the second current is 1 transistor Omega less then the first one. So basically the current goes trough all the transistors flipping their state over, but a second comming right behind flipping them back on the same path, but since the second is slightly less powerfull it wont be able to flip the last transistor like the first current so that's state will remain in a changed state while all others they went trough revert back to their original, effectivelly only changing a deep transistor. Now obviously this would technically halv the speed of the processor, however the additional dimension of verticality would multiply the processor output. So just one level would bring back to a regular processor, and a second level (3 levels in total) would already double, while a third level would quadriple the process power, quickly scaling up the processing power. I don't think heat would be an issue here, as the system already made out of heat transfaring material, it would be harder to cool, and heat up equally fast of how it increases process power, but you would only need better cooling and cooling was the limit of process power anyways so nothing change there, this is more of shrinking the processor but increasing the cooling unit so mass should be likelly equal. Other question is, how do you govern the current to hit the right transistor as it goes trough others? Simple, electric spin can be easilly lined up with magnetic field, you just use a tiny magnetic field (or even use the systems innate field) to keep it consistent and only let trough electrons that fits trough a spin gate, so their path will be predictable at all times. (they should do this on current processors too anyways).

Also I think that Gate-All-Around will be a revolution on the radiation harden transistors, as we have seen with the resilience of FinFet

15:43 - The field effect trnasistor was concieved and postulated as early as the late 1920'ies. Then however, no semiconductor could be made to sufficient purity, though...

Most of this followed my 45 years working in the electronics field. The technology marches along. I hope the USA keeps pace.

0:30 Nanopotatowaffles!

Hughes developed this tech in 1985. Good luck finding out what happened to it. :)

Sir, I could listen to you say the word "dibble" all day

Backside power delivery is kind of funny. You can imagine some engineer raising their arms and putting their hands on their head, exclaiming, "OH NO, it's upside down. We've been doing it wrong the whole time!" They seem to have prioritized power (because it won't work without power) as the first layer and worked it out backwards. And some time later, after some frustration, they figured it would work better in reverse order, data line first. And the anecdote goes, "we'll never ever talk about this again." "Marketing says they're going to call it PowerVia." And the guy's head drops, and thinks to himself, "I'm just never going to hear the end of this."

I really enjoy your channel it takes me back to my Electronics days but I'm a software engineer now. But I studied electronics when I was young. Its interesting they will be able to get to n2 by using established techniques 30% power gain is significant even if performance was to stay nearly the same. Do you think gate all around will make it into high power devices like desktop CPU's

When im looking at these 3d shapes, i can never determine what exactly is a source and drain there...

So the SiGe portion is etched away and the Si blocks just hang in the air...? How does that work?

so the perfect transistor is just a miniature switching relay.

Silly question: can we make a double-sided chips? As we are making double-sided PCBs? So we can make 2x more transistor per sq.mm.

"Some guy starts playing darts and billiards in a pool hall."

Hi, great Video! I wonder can we expect such GAA transistors also in analog applications like RF power amps?

I have little idea what you’re talking about, however it is super interesting.

What's not discussed in this video is the rising design and mask costs that will mean these process nodes are only viable for customers with extremely-high volumes, or those that can charge very large margins on their chips.

Until my PC is free from spinning parts, pumping liquids and other anti-meltdown 'features' I won't feel anywhere near the promised future.

going to the SRAM cells. I don't think they're by ST because the MSP430 is made by Ti... Unless I'm mistaken and ST manufactured or designed Ti's MSP430...

2025-2026 will bring the biggest improvments to semi-conductors until they switch to germanium after 1nm.

Thank you very much for these uploads. Great job.

This was suggested about 1970 at TI ,but was not persued.

Thanks!

How about TEMPERATURES of operation and RADIATION and VIBRATION stress resistant?

waiting for cpus to use stacking and trying to bump up core counts with out energy counts ones you crystalize a formula in to a transister arrey and lipograpth the function like we want to go as small as possble anyway right?

Always so fascinating ... and if I understood more than a fraction of it, just think of the descriptors I could be using. But since I don't I can't. But much thanks nonetheless.

I’d been hearing about gate all around development since about 2015.