- cross-posted to:
- becomeme@sh.itjust.works
- cross-posted to:
- becomeme@sh.itjust.works
I didn’t check the associated paper, only the article itself.
For now this sounds a lot like a curiosity, but this might be useful in the future - if the healing happens under less than ideal conditions, faster, and for wider cracks, it could increase long-term resistance for key applications. I wonder if some vibration (including gentle heating) couldn’t also help.
A potential issue is however air. The experiments were performed with platinum (that doesn’t give a damn) in vacuum, but in real life you got oxygen and even nitrogen potentially leaking into the fractures, binding themselves into the metal, and saying “NOPE, IT’LL STAY LIKE THIS”. So your best bet would be perhaps alloys that are harder to oxide, or even crystalline structures that already have oxygen.
Yea I was going to say I thought we already knew about metals welding together in a vacuum and rust is what keeps it from happening in the atmosphere.
I found the abstract of the (mostly paywalled) nature paper more helpful.
This seems interesting, though so early days it’s hard to tell how practical it’ll end up being, especially since it sounds like it relies on the stressed state of the metal. If I understand right, they’re causing more cracks and in the process that’s cold welding other parts of the metal back together at the same time. And cold welding needs a vacuum, so it could be impractical in that sense too, I’d think.
Bearing in mind also this is a single study, so it remains to be seen whether the findings are replicable.
I’m interested to see where this goes.