the critical field and critical current seem very low … This means you can’t actually push big current through this thing (yet). You can’t make a powerful magnet, and you can’t make viable power lines
The method to produce this material as described in the related paper [1] is fairly simple and could be done at home with a $200 home metal melting furnace from amazon and the precursors (which also seem to be fairly standard easy to obtain metals)
Read this comment thread from SC researchers: <reddit link removed>
Lots of problems with the paper, they claim. It is not up to the standards of current SC research. One of them says Dias’s work shows more merit than this.
The only drawback is that LK-99 is polycristalline… Levitating trains and computers, electronics, are a stretch as long as the material is not monocristalline.
Power cables are currently (heh) designed to operate below 90degC, because after this you get thermal runaway and the conductor melts. That’s already within the operating range of this.
from what i read, it doesn’t seem like you’re able to push much current through it, which makes power cables an unlikely application in its current (heh) form
no i know many of the applications, its huge if true! i understand that, but almost everything like this comes with trade-offs, and i was wondering if there are any here that would make it non-viable for some/all applications
The claimed saturation current is very low. If this is inherent and not just a first-try thing it will be less-good than permanent magnets for doing many magnetic-field things and less-good than Aluminum for some current-carrying things.
It’s a perovskite, in semiconductor applications these have stability and durability problems.
It might also be a scam. This would make it useless.
In amongst that discussion is a lot of reason to hope this will be better, several note that the researchers made a low quality sample “spongy crap” and that in other superconductors made at that quality are just as limited, only becoming useful when better quality samples are made
anyone with a better understanding able to articulate potential trade-offs/complications to using this in practical applications?
*edited:
more discussion: https://news.ycombinator.com/item?id=36864624
Insane capacity batteries
Lossless power transmission via wires
Better magnetically levitating trains
Much more power efficient computers, electronics
The list is huge
The only drawback is that LK-99 is polycristalline… Levitating trains and computers, electronics, are a stretch as long as the material is not monocristalline.
It is huge nethertheless.
Power cables are currently (heh) designed to operate below 90degC, because after this you get thermal runaway and the conductor melts. That’s already within the operating range of this.
from what i read, it doesn’t seem like you’re able to push much current through it, which makes power cables an unlikely application in its current (heh) form
no i know many of the applications, its huge if true! i understand that, but almost everything like this comes with trade-offs, and i was wondering if there are any here that would make it non-viable for some/all applications
The claimed saturation current is very low. If this is inherent and not just a first-try thing it will be less-good than permanent magnets for doing many magnetic-field things and less-good than Aluminum for some current-carrying things.
It’s a perovskite, in semiconductor applications these have stability and durability problems.
It might also be a scam. This would make it useless.
In amongst that discussion is a lot of reason to hope this will be better, several note that the researchers made a low quality sample “spongy crap” and that in other superconductors made at that quality are just as limited, only becoming useful when better quality samples are made
that’s great news! let’s hope replication and peer review is smooth!
It would be a real bummer if this came out to be untrue. However it’s simple enough to replicate, so we will know soon enough