Superconductors basically means you can run your PC’s processor at 1% of its current energy draw. So now take a mobile phone processor, recreate it with superconductors, and you suddenly have a device that can do a massive amount of computations for years on a single AA battery
Not just that, but you also have things like MRI, CT, and PET imaging in the medical world that would suddenly not need liquid helium and nitrogen for operation. Scientific instruments like NMR and high resolution FT-MS machines will stop using all the liquid helium and nitrogen. It will save are rapidly disappearing helium resources and allow for that to be used for other things.
Then there is mass transit that can be developed. The list goes on.
Simple energy transmission. A room-temp superconductor has the potential to fundamentally change the entire electrical grid if it were even remotely scalable.
It’s hard to overstate how immensely expensive and complex energy transmission currently is.
The 127C is the critical temperature. With other superconductors, if you get the material below the critical temperature, its starts superconducting. From the descriptions I’ve seen, the meaning of critical temperature is the same with this material, so it should superconduct at 23C just fine, presuming it is a superconductor.
Correct. So why are you concerned with it not working at well over boiling water temperatures? This is about a room temperature superconductor. 127 °C is not room temperature.
Superconductors basically means you can run your PC’s processor at 1% of its current energy draw. So now take a mobile phone processor, recreate it with superconductors, and you suddenly have a device that can do a massive amount of computations for years on a single AA battery
Not just that, but you also have things like MRI, CT, and PET imaging in the medical world that would suddenly not need liquid helium and nitrogen for operation. Scientific instruments like NMR and high resolution FT-MS machines will stop using all the liquid helium and nitrogen. It will save are rapidly disappearing helium resources and allow for that to be used for other things.
Then there is mass transit that can be developed. The list goes on.
Simple energy transmission. A room-temp superconductor has the potential to fundamentally change the entire electrical grid if it were even remotely scalable.
It’s hard to overstate how immensely expensive and complex energy transmission currently is.
You aren’t going to heat something to 127 °C with an AA battery.
The 127C is the critical temperature. With other superconductors, if you get the material below the critical temperature, its starts superconducting. From the descriptions I’ve seen, the meaning of critical temperature is the same with this material, so it should superconduct at 23C just fine, presuming it is a superconductor.
Most people don’t consider 127 °C to be room temperature.
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“Room temperature” in this context means “above 0 °C”.
Correct. So why are you concerned with it not working at well over boiling water temperatures? This is about a room temperature superconductor. 127 °C is not room temperature.