1.5nm is more like 10 atoms across, given that, for example, a C-C bond is 0.154 nm. Not that that helps tremendously :)

https://en.wikipedia.org/wiki/Monocrystalline_silicon has 0.5nm for the lattice spacing, distance between Si atoms ranges somewhere between 0.3nm and 0.5nm, I guess. Even if you go to graphene instead of Si wafers, I don’t think you’ll get more than three atoms within 1.5nm, as graphene is not a cubical lattice.

Unit cell of Silicon is about 5 angstroms (0.5 nm), so we'd be at about 7 atoms wide for a diamond cubic structure (I think).

I don't think we can actually make chips out of carbon...

It was an number for the length of a chemical bond that I had easily to hand, other bonds aren't significantly different, definitely not 5 Angstrom.

Also, people working on graphene and related materials are trying damn hard to make chips out of carbon ;)

Unit cell is 5.43 Angstroms, according to this site: http://hyperphysics.phy-astr.gsu.edu/hbase/solids/sili2.html. Of course the bonds by which the cell is constructed are smaller.

That what I always wonder. There's gotta be a limit in there somewhere... right? Maybe? But they just keep finding new ways to make 'em even smaller yet. How far will we go, and what will our devices and industry look like by the time we can't go any further?

It's quite possible we're at the cusp of the plateau already. For many years planes kept getting faster and faster, until one day they didn't. It may be the same with processors. For years they'll keep getting smaller and smaller, until one day they don't. In fact, this already happened with clock speed 10 years ago. The top Pentium 4s, while certainly worse than the Haswell i7s of today, have about the same clock speed (3.8 GHz or so).

That's due to thermal and electrical limits of Silicon and whatever you are using to insulate (Silicon Dioxide)... having a semiconductor with a higher bandgap (Such as many III-V semiconductors, such as indium gallium arsenide), you can have a much higher clockspeed.

I'm really interested in this, could you please explain more? My impression is that the heat from subthreshold current is what's limiting today's CPUs. How does a higher bandgap help you achieve a higher clockspeed for the same power density?

> For many years planes kept getting faster and faster, until one day they didn't

Planes are still getting faster and faster. Though now they are mainly unmanned.

HTV-2 Falcon scramjet reached 13,201 mph on 22 April 2010.

NASA X-43 reached 6,600+ mph.

I don't know if you'd count these one-off experiments in the same league as making aircraft that you can actually turn a profit manufacturing and operating. That game seems to have dried up at about the size and speed of modern jetliners, given the issues we've had with operating supersonic commercial aircraft.

I'm sure somebody in a lab somewhere can make a single processor that's ridiculously fast compared to anything you can buy, but being able to manufacture usable, reliable CPUs in quantity and cheap enough to turn a profit on selling them is a whole 'nother ballgame.

I don't think that there is a way to go smaller than an atom. Most likely, there will be a sifht in technique. My guess is quantum computing, but who knows.

I don't think that quantum computers are made of subatomic components, nor are atoms split in the process.