Electricity is repulsion in current
On May 7, 6:42*pm, foolsrushout wrote:
wrote:
On May 7, 1:50 pm, foolsrushout wrote:
wrote:
On May 7, 2:46 am, foolsrushout wrote:
wrote:
On May 6, 8:06 pm, "caveat" wrote:
wrote in message
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Like charges repulse therefor electricty is a push of one electron
against another by their mutual repulsion. The push flow of current is
a result of electron repulsion one against another.
Mitch Raemsch; Twie Nobel Laureate 2008
How fast is this push flow?
Is it any faster or slower than the actual flow of the electron itself
through the circuit?
Chris; NOT Twie Nobel Laureate 2008
Why don't we accelerate electricity.
Define "electricity".- Hide quoted text -
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A repulsive flow.
Gas under pressure satisfies that definition.
Want to try again. Think you can get it right
in 10 attempts?
You actually have the entire internet available
to you. Try researching instead of making up
"science" as you go along. Google is your friend.
Unless you're an autist, of course.- Hide quoted text -
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Same charges repulse. Move one and it will repulse the next. That is
electricity in a nutshell.
Mitch Raemsch; Twice Nobel Laureate 2008
So the subject line you started this discussion under
is incorrect? If you're using one particular model of
electric current that has them jumping from atom to
atom what does the nature of the atom have to do with
electric current, and why do the electrons jump from
shell to shell within the atom as part of electric
current? One could just as easily say that the atoms
are unhappy with an extra electron and form the
working mechanism that forces electrons to move
sequentially. Where does the resistive heating from
current come from?
How about field theory and electric current flow.
That's just scratching the surface. There is no
"electricity in a nutshell." But I have to believe
that's the extent of your knowledge on this subject.
Just enough to get you into trouble.- Hide quoted text -
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Electric current is repulsive by the electron's nature.
Mitch Raemsch; Twice Nobel Laureate 2008
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