If the path of the photons is indeed transverse to the flow of charge, millions of transistors could share a single wavefront.
They seem like related attempts at creating optical processors.
It makes me raise so many questions. 1 PHz corresponds to a wavelength of 300nm, UV light. How does it make sense? It can't be the transistors we are used to, that's all quantum weirdness at this point. How do you even use them? Things like copper wires feel meaningless at these scales.
A 1 petahertz chip would be 200,000 faster than a 5 gigahertz chip. You've skipped past the terahertz range.
They say the light pulse is 6.5fs FWHM, so they weren't able to switch it on and off 1.6 quadrillion times per second; it's just that the transition from on (29nA) to off (<1nA) was only 630 attoseconds long, which is what they're describing as "petahertz". But "petahertz" implies a whole cycle time under a femtosecond, a cycle which would involve two transitions, which would presumably be 1.26 femtoseconds at this speed. (If they measured the speed of the off-to-on transition, I missed it skimming the paper.) And the actual light they're making the 6.5fs pulse out of is a "supercontinuum laser beam that spans over 400–1000 nm". That's still blue enough to raise some concerns about device longevity (though maybe graphene will prove tougher than certain other semiconductors which shall not be named here), but not to the same degree as if they were using actual petahertz light.
I think the 2× exaggeration is sort of forgivable, and nothing else seems to be intentionally misleading, but it would still be easy to draw incorrect conclusions from the headline.
It would be such a strange mistake to occur on a paper about a topic of this caliber that I feel like I must be missing something.
https://en.wikipedia.org/wiki/Orders_of_magnitude_(time)#Les...
So, ask a trusted peer whether this is a something-burger or an attempted academic pivot. Since life is too short to spend on science you can't call your own: look at invites from ASML/TSMC/SMIC. That's what happened with Sn vapor lasers-- famously fickle things. The company that first got it to work properly (Cymer) isn't even on the relevant wikipedia page? And on the ASML they are associated with DUV? Really pushing the good faith here I think. I first paid attention thanks to interest from ASML.
(Disclaimer: don't know any experimentalists working in the exact domain)
E: sn vapor (laser-pumped) light source
I believe I recently saw on goog schol other attempts at vuv lasing/light emission using very similar setup of laser pumping in si-gr (Can't remember the exact search terms I used at the time, or how unsuccessful they were)
E: here's one (2019 dissertation; ndyag ns-pulsed laser probe) which openly states the underlying motivations. You can also check the phd thesis when it comes out, usually they won't hold back on their informal motivations at defence-time :)
https://tesidottorato.depositolegale.it/bitstream/20.500.142...
If I hadn't read your doubts about the stability above, which reminded me of the limited lifetime of sn vapor sources (there due to contamination of optics), I wouldn't have imputed those motivations to TFA
E2: one from 2019 on VdW vuv detectors (ns response time)
https://pubs.acs.org/doi/full/10.1021/acsphotonics.9b00729
E3: I also thought that the mention of "ambient conditions" in the uni PR was slightly out of place outside the context of light sources.
https://ieeexplore.ieee.org/document/6259401 https://pubs.aip.org/aip/rsi/article-abstract/84/6/063104/35...
Lots of intertwining uh avenues of research!
(Without full fledged devices, it's easy to lapse into pareidolia on spectras & motivations :( )
ChuckMcM•8mo ago
It's also kind of funny that you could mine the shit out of Bitcoin with something like this, which would either pay for itself or crash Bitcoin, hard to predict.
Someone•8mo ago
Bitcoin has a built-in mechanism to counteract improvements in hashing speed (either because of hardware getting faster, algorithmic improvements, or more hardware getting devoted to hashing).
See https://en.wikipedia.org/wiki/Bitcoin#Mining: “The difficulty of generating a block is deterministically adjusted based on the mining power on the network by changing the difficulty target, which is recalibrated every 2,016 blocks (approximately two weeks) to maintain an average time of ten minutes between new blocks“
I think there’s more than enough range available here to handle a million-fold increase in hashing power.
inhumantsar•8mo ago
if someone had a monopoly on chips like these, they could dominate the network and freeze out other miners. which would likely tank the network and make those BTC worthless
Someone•8mo ago
I guess that didn’t happen because making ASICs is relatively easy, but even if it isn’t, what would be in it for a potential monopolist to tank the value of bitcoin in that way? They better take a large but not overly large part of the market and keep mining money for a long time, only speeding up when a competitor steps in.
jorvi•8mo ago
Shorting BTC. But you'd have to gather a humongous mining farm / pool in secret, wait until right after the recalibration and then turn on everything at once, mining those 2016 faster. People would panic, enabling you to close your short positions.
After those 2016 blocks you can just keep mining for a regular return, although I'd just sell the farm to an organisation interested in doing so.
It's a fun theoretical attack, if capital intensive. And aside from the short positions (which you can cover instead of going naked), your capital isn't at risk because the worst result is that you'll own a crypto mining farm.
sigwinch•8mo ago
Someone•8mo ago
Bitcoin is fairly popular among criminals, so you might also get some people visit you to argue that is best for both of you to give them back the money they lost, using strong arguments such as threats of bodily harm.
TheOtherHobbes•8mo ago
iwontberude•8mo ago
Devasta•8mo ago
The difficulty will have gone through the roof and transaction processing time by the rest of the network will then slow to a crawl.
TZubiri•8mo ago
HPsquared•8mo ago
wslh•8mo ago
bee_rider•8mo ago
phkahler•8mo ago
Does handing transactions require similar amounts of power to mining?
Edit: also, if transactions are ultimately handled by just one or two entities, there will be no point to bitcoin any more.
kragen•8mo ago
ted_dunning•8mo ago
The real answer hinges on the leverage of mining one hash to certify multiple transactions.
bee_rider•8mo ago
I’m under the impression that “handling transactions” in bitcoin and mining are the same thing. (Although I don’t work in cryptocurrency so maybe the misunderstanding is on my part…)
Sohcahtoa82•8mo ago
- Broadcasting the transaction throughout the network so that all nodes (including miners) are aware of it
- Miners confirming transactions by solving a block
When a miner solves a block, they earn both the block reward (Which will eventually become zero) and the fees paid by the sender.
Theoretically, as time goes on an the value of Bitcoin goes up, the value of the fees will be high enough that it will make up for the lack of the block reward.
So the original question of "Does handing transactions require similar amounts of power to mining?"
The answer is basically yes. Mining is what confirms transactions. A new block is added to the chain, with each block containing several transactions.
fennecfoxy•8mo ago
I've seen discussion that as the block reward falls, transaction fees will go up but this doesn't seem like enough. Hash rate will fall and people will sell up and get out of it. If the hash rate falls enough doesn't that open the network up to fraudulent transactions if a big player (in terms of hash rate) decides to go rogue? The whole 51% takeover thing. Seems like the entire market cap of bitcoin will pop at some point in the future.
Sohcahtoa82•8mo ago
The reward is currently 3.125 btc. It gets cut in half every 210,000 blocks, which is ~4 years. It'll drop to 1.5625 in 2028, 0.78125 in 2032, and so on. It won't hit 0 btc until the year 2140.
Secondly, even with 51% of the hashing power, a rogue mining org can't create fraudulent transactions. A block with invalid transactions will be rejected by the rest of the network.
Instead, it does allow a rogue miner to pick and choose which transactions it confirms in a block. Still bad, but it's not like they can steal bitcoin from people. And if they just sat and mined empty blocks, they wouldn't earn the transaction fees. The only way they could profit is to short the hell out of bitcoin, start mining empty blocks which effectively is a DoS on bitcoin, then cover the short after it plummets in value.
To do such an attack wouldn't just require immense money to buy the mining equipment, but also a ton of money to put up as collateral for the short.
Sohcahtoa82•8mo ago
It DID answer the question.
> The real answer hinges on the leverage of mining one hash to certify multiple transactions.
That's exactly how mining works.
A block is mined when all the data for a block (which includes all the transactions of the current block) plus a nonce gets hashed and the resulting hash has a value that satisfies the current mining difficulty level. If hash doesn't satisfy it, you try a new nonce. Mining hardware just tries millions/billions of nonces per second.
It's possible (though extremely unlikely) that you could solve a block in only a single hash.
I think what a lot of people don't understand is that the difficulty scales with the amount of hashing power on the network. If blocks are being solved too quickly, the difficulty rises. If they're too slow, it goes down. Difficulty really just changes the odds that your hash meets the requirement. It doesn't change the actual difficulty of computation, just the odds of success.
slashdev•8mo ago
temp0826•8mo ago
slashdev•8mo ago
I've got a friend who threw out $20M in bitcoin (at today's prices) by mistake. I wonder how often he thinks of that.
temp0826•8mo ago
slashdev•8mo ago
I've managed to lose 60% of my networth over the last 5 years. Mistakes were made.
thephyber•8mo ago
indoordin0saur•8mo ago
jazzyjackson•8mo ago
indoordin0saur•8mo ago
gosub100•8mo ago
Has anyone even made a flip-flop or latch with any optical transistor yet?
jlokier•8mo ago
That said, you don't need flip-flops or latches to calculate SHA-256 for mining Bitcoins. You only need them at the edges of the circuit, to use the results. But you can do that with electronics at the edge, if you want to avoid stateful logic in the all-optical part.
dgfl•8mo ago
It might turn out to be great for the applications that they point out in the paper itself, not so much for logic. I would say bitcoin mining discussions are a bit premature, and potentially not relevant.
programjames•8mo ago
These exist:
https://ultrafast.mit.edu/
knome•8mo ago
at petahertz (10^15) speeds, you could sacrifice a lot of space for larger components, and still come out on top vs gigahertz speeds (10^9) by doing more work but a hell of a lot faster, no?
if you can build a chip that's a million times faster, you can sacrifice 3/4 of that speed to doing more work with fewer components and still be 250,000x faster.
formerly_proven•8mo ago
Jabrov•8mo ago
adgjlsfhk1•8mo ago
colechristensen•8mo ago
nyeah•8mo ago
This is assuming you use a waveguide and travelling waves to send the electrical signals. If you charge up the whole line then, sure, that's slower.
tbrownaw•8mo ago
hulitu•8mo ago
So more like an optical triode (the transistor apnplifies).
stretchwithme•8mo ago
Just don't sell it all at once.
thephyber•8mo ago
BTC Mining adjusts based on difficulty. IIRC (I haven’t looked into the specifics in a few years) the protocol will adjust so a block should be mined every 10 mins or so. If there is a massive leap in hardware capabilities, the protocol automatically throws A LOT more difficulty at the mining problem.
One way to crash BTC using a massive hardware advance: dominate the mining for ~ 2 weeks, long enough until until the mining difficulty is adjusted upwards and stop mining. Much higher difficulty + only older hardware doing the work = very slowly processed blocks and a growing backlog of transactions. Eventually the protocol would reduce the difficulty to match higher block transaction rates, but the attack could be maintained by thrashing the miner on/off just after the difficulty is adjusted upwards/down.