Pulsed laser deposition at wafer level is a game changer

cookingrobot · on June 27, 2024

Does this help with compute, or just MEMS and radio?

ak217 · on June 28, 2024

Not sure about compute. But

> Achieving higher scandium concentrations in aluminum nitride films can help increase RF filter performance. Pulsed laser deposition can take the scandium concentration in the film to at least 40%, up from the previous 30% limit

The first thing that came to mind when reading this was RF synthetic aperture performance for jamming-resistant directional antennas in military applications. These seemingly incremental improvements can have huge real world consequences.

Imagine the Starlink antenna but with 10x the performance, or a radar that can withstand 10x the jamming or hide completely because it needs 10% the power. I wonder if that's what's possible here.

ak217 · on June 28, 2024

(correction: phased array, not synthetic aperture)

osnium123 · on June 27, 2024

I think it’s more for MEMS and RF applications. These techniques don’t have enough conformality for modern fin and nanosheet based transistor logic.

mensetmanusman · on June 27, 2024

PLD is currently required for deposited materials that have, for example, high Faraday rotation (https://en.m.wikipedia.org/wiki/Faraday_effect)

These are types of important material properties for the future of compute if we are to use light based computation. E.g. how can one make a medium for light to only propagate one direction.

__lbracket__ · on June 28, 2024

Like everything in the last 20 years (silicon photonics, graphene, spintronics,...) "it promises to one day revolutionize computing" (a day that never comes !)

m463 · on June 28, 2024

I thought there was a hn article about intel's just announced silicon photonics product:

https://news.ycombinator.com/item?id=40812465

:)