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TSMC Achieves Major Breakthrough in 2 nm Manufacturing Process, Risk Production in 2023

I wonder what my old solid state physics lecturer would say reading this. I remember being taught once we got below 10nm all hell would break loose and we'd need entirely new form of solid state devices. Line traces would be too small to stop quantum tunnelling of electrons and devices couldn't operate. 2nm seems surreal for architecture that's only several atoms in size. The physics of current transport must be highly affected as the size gets so small. I honestly didn't expect us to keep going much longer after 10nm.
 
Optical guy here, the issue with anything past EUV is it cannot be focused anywhere near the precision of EUV. Look at Chandra and the terrible resolution it gathers in x-ray versus what Hubble can do in EUV. X-Rays ignore most matter including the exotic mirrors (some are basically diamond coated) used to focus EUV.
 
I mean, true, but do we need it to be?
Yes, you're making some very big assumptions there. For one, Taiwan is not under the restrictions imposed by trade embargo and two, there is a strategic tax advantage to having a manufacturing facility stateside.
 
I wonder what my old solid state physics lecturer would say reading this. I remember being taught once we got below 10nm all hell would break loose and we'd need entirely new form of solid state devices. Line traces would be too small to stop quantum tunnelling of electrons and devices couldn't operate. 2nm seems surreal for architecture that's only several atoms in size. The physics of current transport must be highly affected as the size gets so small. I honestly didn't expect us to keep going much longer after 10nm.

It's just a marketing name, there is nothing actually 7nm about their "7nm" node and "2nm" won't be any closer to reality either.
 
I wish companies to use old nodes 16nm or 22nm or 28nm. It's heat density is less and more easily for cooling :D
 
It's just a marketing name, there is nothing actually 7nm about their "7nm" node and "2nm" won't be any closer to reality either.
No, that's not true. The "7nm" refers to the dimensional size of the smallest component within the structure of an individual computing unit. The same will be said of the "2nm" as the smallest nanosheet of the "MBCFET " process will only be 2nm thick. So the nanometer classification labels are correct within the context of their definitions. This is where a lot of the confusion comes from.

For example, with Intel's 14nm+++ etc line up, they keep getting blasted for not making more progress sooner and yet that process has product what was widely considered the fastest silicon in the world until just recently with AMD's Zen3. The refinements Intel made where solid and enough to keep them in the lead. It is only know that they need to kick things up a notch or two to match AMD's/TSMC's new hotness. Intel's new 10nm process will likely meet that challenge, but even if they stay in second they're not lagging behind by much. So even though it a 10nm process, it's still competitive with the 7nm, 5nm and so on offer elsewhere. Intel's not the performance king currently, but that will not last. They will make strides forward and then others with make their advances. This is how the games has been played for decades. It will continue..
 
No, that's not true. The "7nm" refers to the dimensional size of the smallest component within the structure of an individual computing unit. The same will be said of the "2nm" as the smallest nanosheet of the "MBCFET " process will only be 2nm thick. So the nanometer classification labels are correct within the context of their definitions. This is where a lot of the confusion comes from.

That hasn't been true for at least 15 years. There is nothing about a TSMC "7nm" transistor that measures 7nm.
 
That hasn't been true for at least 15 years. There is nothing about a TSMC "7nm" transistor that measures 7nm.
What about transistor fin distance? I think I know what the definition is. They do it to reach max process fidelity. You cannot lithographically get any finer than the process designation.
 
Let's remember that TSMC 7nm EUV transistor is 22 by 22nm, while 14nm+++ Intel transistor is 24 by 24nm, cough.
(as measured by some German dude, who compared L1 cache in particular)

2nm should be... around 18nm I guess.... :D
 
Let's remember that TSMC 7nm EUV transistor is 22 by 22nm, while 14nm+++ Intel transistor is 24 by 24nm, cough.
(as measured by some German dude, who compared L1 cache in particular)

2nm should be... around 18nm I guess.... :D
Actually, that sounds about right.
 
Let's remember that TSMC 7nm EUV transistor is 22 by 22nm, while 14nm+++ Intel transistor is 24 by 24nm, cough.
(as measured by some German dude, who compared L1 cache in particular)

2nm should be... around 18nm I guess.... :D
If this is true, Intel architecture is not that great, after all.
 
Except that it was king of the performance hill until Zen3. Performance is what counts, how something is made is of a secondary concern.
Have you looked at this? I won't be the judge whether this guy knows his beef, but there are some yield benchmarks to the dismay of fanbots of a very vocal community.
 
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