Even assuming that an outer core of liquid iron exists, there are major
problems with the dynamo theory. Joseph Cater writes:
Scientists are somewhat vague as to how a magnetic field could extend 2,000
miles beyond an electric current. It requires a very powerful current to
produce even relatively weak magnetic effects a very short distance above
the flow. The electrical resistance of iron, at the alleged temperatures of
the core, would be staggering. A steady flow of electricity requires
constant potential differences. How are such potential differences produced
and maintained in this hypothetical core?
The magnitude, width, and depth of such currents would have to be
unbelievable to extend the magnetic field even a small fraction of the
distance required, and the EMF [electromotive force] required to produce it
would be even more incredible. Where could such an EMF come from? So far,
scientists seem reluctant to explain this, especially since these currents
are confined to a ball and would therefore follow closed paths. [3]
Hi,
It would be a good a idea to read 'Twilight' by the Tibetan Abbot, Dr. TL Rampa.
Please, do.
Let My Thoughts, Words and Deeds Bring Good And Fortune; To My_Self, My Environment And To Other Beings,. Thank You,my God.
________________________________
From: Dean D <[email protected]>
To: [email protected]
Sent: Tuesday, 9 April 2013, 1:59
Subject: [allplanets-hollow] how could a magnetic field could extend 2,000 miles beyond an electric current
Even assuming that an outer core of liquid iron exists, there are major
problems with the dynamo theory. Joseph Cater writes:
Scientists are somewhat vague as to how a magnetic field could extend 2,000
miles beyond an electric current. It requires a very powerful current to
produce even relatively weak magnetic effects a very short distance above
the flow. The electrical resistance of iron, at the alleged temperatures of
the core, would be staggering. A steady flow of electricity requires
constant potential differences. How are such potential differences produced
and maintained in this hypothetical core?
The magnitude, width, and depth of such currents would have to be
unbelievable to extend the magnetic field even a small fraction of the
distance required, and the EMF [electromotive force] required to produce it
would be even more incredible. Where could such an EMF come from? So far,
scientists seem reluctant to explain this, especially since these currents
are confined to a ball and would therefore follow closed paths. [3]
[Non-text portions of this message have been removed]