mo.com<mailto:vortex-l@eskimo.com>
Subject: RE: [Vo]:What is special about ~630 eV ?
From: Axil Axil<mailto:janap...@gmail.com>
* The gain might not be thermal, but ultraviolet light.
Technically , if the main mechanism for gain is photonic in the 630 eV range –
that
From: Axil Axil
➢ The gain might not be thermal, but ultraviolet light.
Technically , if the main mechanism for gain is photonic in the 630 eV range –
that mass-energy level is categorized as a soft x-ray which is stronger than
EUV.
If this turned out to be a Mills-type of hydrino
The gain might not be thermal, but ultraviolet light.
On Thu, Jun 20, 2019 at 6:29 PM JonesBeene wrote:
> Yes.
>
>
>
> Basically I am simply looking for connections which can explain the
> thermal gain with the fewest conflicts.
>
>
>
> That is not an easy task – but this looks far less like
Yes.
Basically I am simply looking for connections which can explain the thermal
gain with the fewest conflicts.
That is not an easy task – but this looks far less like nuclear fusion than
does P electrolysis.
From: mix...@bigpond.com
In reply to JonesBeene's message of Thu, 20 Jun 2019
In reply to JonesBeene's message of Thu, 20 Jun 2019 13:02:01 -0700:
Hi,
[snip]
>Robin,
>
>The separation distance of dense deuterium is about 2 picometers in Holmlids
>model
So, when you were talking about 2 nm, you were talking about the size of the
cluster as a whole then rather than the
Robin,
The separation distance of dense deuterium is about 2 picometers in Holmlid’s
model
From: mix...@bigpond.com
… 2 nm = 20 Angstrom ~= 28 times the separation distance of the of the D nuclei
in a Deuterium molecule. If Deuterium molecules are too big to undergo fusion
using the strong
In reply to JonesBeene's message of Thu, 20 Jun 2019 07:00:24 -0700:
Hi,
[snip]
>The strong force may become involved at this point to provide the binding
>energy in similar way that gluons bind quarks.
[snip]
2 nm = 20 Angstrom ~= 28 times the separation distance of the of the D nuclei
in a
Oops,
Should be
“Two nm is the separation geometry for maximum appearance (compressive force)
of the Casimir force”
Instead of
“Two nm is the maximum separation geometry for the appearance of the Casimir
force”
IOW - the Casimir force is seen most strongly within a range of 2-12 nm - but
One detail which may figure into the understanding of the new Mizuno work is
the wavelength of photons at 630 eV.
Dense deuterium as it is characterized in about two dozen papers will have a
binding energy of ~630 eV – at least that is the energy signature which has
been measured. Mizuno
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