- cross-posted to:
- technology@lemmygrad.ml
- technology@lemmy.ml
- cross-posted to:
- technology@lemmygrad.ml
- technology@lemmy.ml
The institute said its facilities had the capacity to produce 12,000 wafers annually, with each wafer yielding about 350 chips.
that’s 1000 wafers per month aka 350 000 chips per month. If this is not mass production, it’s not far from it.
The US has been trying to build advanced semiconductor plants for =<7nm chips. Safe to say that all of it is doomed by this development if it isn’t already by all the problems they had trying to build chip plants in the US.
The platform aims to share its design and processing expertise with industry partners to accelerate the commercial adoption of the technology across 5G, 6G, artificial intelligence (AI) data centres and quantum computing networks.
So there’s already consumer applications on the way. How long until we get smartphones and computers with one of those as CPU?
I’d expect within half a decade for this tech to become widespread.
hell yeah
I’m a little surprised by this… I was at a thrift store the other day and found a book from the 90s on telecommunications where they mentioned photonic chips designed by AT&T and IBM back in the mid-90s. They were talking about photonic switches and whatnot but also that there were chip designs as well. How come it has taken this long to actually produce such chips I wonder?
I think there’s a number of factors here. It’s often very hard to go from making a proof of concept work in the lab to actually scaling it into mass production. This is especially so for companies that want to see a clear path to profit. If something can’t be made to work within a certain budget, then it’s probably going to be abandoned. Whatever new tech money is allocated towards also has to compete with scaling up existing tech. So, if a company is already making good money off silicon chips, there’s little incentive to divert huge amounts of funds towards making alternative substrates work. Shareholders want to see quarterly profits after all. And this is why we constantly see these kinds of discoveries published in research, but never actually commercialized.
What’s different now is that the US is actively trying to choke off China’s chip access, and China is investing in chip development at state level in response. The logic becomes different because a moonshot project using an alternative substrate has the potential to leapfrog existing tech entirely. Profitability is no longer the primary driving force here, the state can pour effectively unlimited funds into commercializing this tech until something works.
that makes sense, thanks