That just the CMFV theory of fusion.
----- Original Message -----
From: Axil Axil
To: vortex-l
Sent: Tuesday, March 04, 2014 6:37 PM
Subject: Re: [Vo]:"Christopher H. Cooper"
Here is my take on nickel and the Curie temperature.
First, the Ni/H reactor will not work well if its operating temperature is
below the Curie temperature. A cold reactor will radiate gamma rays.
At low temperatures, the nuclear reaction is not part of the magnetic based
positive feedback loop and gamma radiation that is produced escapes to the far
field and is not thermalized.
When the operating temperature rises above the Curie temperature, organized
global ferrimagnetism is "destroyed" leaving the magnetic domains in a
localized though organize state of magnetic vortex formation, where they
remain until the metal cools at shutdown.
These local vortex formations provide templates upon which the solitons will
condense. These quantum cavities absorbed both gamma radiation from nuclear
reactions and infrared radiation from the reactor structure and amalgamate
these waves into a XUV soliton waveform resonant with the diameter of the
quantum cavity: about 1 to 2 nanometers.
These soliton waveforms produce anapole magnetic field on the atomic scale of
about 10^16 tesla. These fields' condense mesons from the vacuum which produces
nuclear cluster fusion reactions in the surrounding matter.
On Tue, Mar 4, 2014 at 8:58 PM, <mix...@bigpond.com> wrote:
In reply to Axil Axil's message of Tue, 4 Mar 2014 16:54:13 -0500:
Hi,
It seems I got the magnitudes reversed.
However consider the following:-
Below the Curie Temperature Ni behaves as a Ferromagnetic material, and
increases the field strength when a current is applied, as it's magnetic
domains
align with the field, and one another.
However as energy is generated in the reactor, and the temperature rises
above
the Curie temperature, the "magnet" is "destroyed" leaving the magnetic
domains
in a disordered state, where they remain as the metal cools toward the end
of
the cycle.
When the next cycle begins, they become ordered once again.
>DGT:
>"After each triggering duty cycle (the triggering sequences producing
>excess heat), the magnetic fields at ~18 cm from the reactor at all three
>locations rose from ~0.6 Tesla to ~1.6 Tesla (DC peak) during each reaction
>period. Such anomalous peak signals were maintained for approximately 3-4
>sec after the HV currents were cut off. "
>
>
>Axil:
>
>The duty cycle is triggered by a high voltage current. After the HV spark,
>the magnetic field measures .6 tesla. The magnetic field grows along with
>the reaction for 3-4 seconds. At the peak of the reaction cycle, the
>magnetic field is 1.6 tesla.
>
>Read it yourself here:
>
>http://www.physics.purdue.edu/people/faculty/yekim/ICCF-18-JCMNS-KH-Pre-2.pdf
[snip]
Regards,
Robin van Spaandonk
http://rvanspaa.freehostia.com/project.html
