"Joseph.D.Warner" wrote in message ...
snipped
Please think about what you're saying. "All" is a mighty big word. Does
sapphire superconduct or quarts or any insulators at low temperatures
and normal pressures?
I did not seem to spell out the Experiment which I had listed into the title.
The experiment I had in mind which Joseph seems to have jogged my memory, for it seems as though I
have so many things on my mind that if I wander off just minorly I run the risk of not completing
what I had started off in doing.
Joseph talks about sapphire or quartz. And I would say they are superconductive but at a temperature
so close to 0 Kelvin.
The experiment I wanted to discuss and prod someone into doing involves fluorine and cesium. Or any
two of the most electronegative and electropositive elements. I just picked fluorine and cesium but
it could just as well be Cl and Ba or I and Rb. What I want to do is to get an Experiment where I
get the cold temperature to release a Self-Current or Spontaneous Current. Perhaps such a thing has
a different name.
I want an experiment where the coldness of temperature of 2 atoms, one electropositive and the other
electronegative, that the push of the electron and the pull of the electron from these 2 atoms
creates a Self Current of electron flow.
So that the Coldness creates electric current without resistance. And that Superconductivity is just
the creation of an electric current because the coldness has made the Electropositive atom push an
electron and the Electronegative has caused a pull of an electron to such an extent that
Electropositive push + Electronegative pull = current creation = Superconductivity
If Experiment can show that the push and pull of electrons when combined with very low temperatures,
that Superconductivity is the creation of a Self Current and that is why there is no resistance
because when you add an outside source of current it just ties in with the pushing and pulling of
the atoms.
So, set up an experiment with say Fluorine and Cesium and cool them to very low temperatures and
look for a Spontaneous current flow. If there is one, then I believe this is the ultimate
explanation of Superconductivity in that you have simply Maximized the
Electronegativity/Electropositivity and also maximized Conduction Bands. Whether Conduction Bands is
separate from Electronegativity is unclear, but we do remind ourselves that Superconductivity is a
complex process and so it is likely that Superconductivity involves both Electronegativity and
Conduction Bands.
Experiment I request: I am looking for an experiment where no outside source of electric current is
applied but wherein upon very cold temperatures a Spontaneous current appears to arise in the test
sample.
If lead with silver film superconducts at 1.8 K, then is there a tiny Spontaneous current at 1.5
Kelvin??? Where Pb is considered the electronegative element and silver considered the
electropositive element and disregarding Conduction bands.
But I still preferr to use Fl and Cs, or I and perhaps K.
If I can get a current creation by lowering the temperature to very cold, then I think I can
completely explain Superconductivity. It would be a tiny current, perhaps milliamperes, but if I can
get current creation then the riddle of superconduction will be closer to a finish.
Archimedes Plutonium,
whole entire Universe is just one big atom where dots
of the electron-dot-cloud are galaxies