Jones Beene wrote:
>
> The next message, not this one, should be more on-topic. It
> will be a mini-essay entitled "Beyond Cold Fusion and the Hydrino".
> will be a mini-essay entitled "Beyond Cold Fusion and the Hydrino".
>
In anticipation of this blockbuster: :-)
The magnetic field calculator in the GSU link shows that a quark (energy loop or disk) with a radius of 4.6e-18 meters and
a displacement current of 1.66e6 amperes has a B field of 2.26e17 Tesla at it's center
which tapers off (by 1/R^3) to 2.26e7 Tesla at 1.0e-14 meters, and 0.000149 Tesla at the 5.3e-11 meter Bohr Radius.
With three quarks (energy loops or disks) working together, the B field from the proton is 3 times this at
the data points.
OTOH, the electron (energy loop or disk) with a radius of 2.81e-15 meters and a displacement current of
2,719 amperes has a B field of 6.07e11 Tesla at it's center tapering off to 1.2e10 Tesla at 1.0e-14 meters,
but still strong (0.09 Tesla) or 911 gauss at the 5.3e-11 meter Bohr radius.
If the magnetic field of the electron repels the proton field or balances the 8.0e-8 newton attractive electrostatic force
between the electron and proton, how can you get a fractional orbit electron?
Frederick

