On Feb 23, 2011, at 4:09 PM, Dennis wrote:
I am not too good at looking at Electron microscope pictures....
perhaps someone here can
help me understand Rossi's pictures in his patents. us20110005506A1
http://www.google.com/patents?
id=84vwAAAAEBAJ&pg=PA1&lpg=PA1&dq=us20110005506A1
+Rossi&source=bl&ots=qIO9bKdbuQ&sig=gHJvMrVVzvM4orfP4ggDk4-
D_YM&hl=en&ei=7a1lTa_1KZCasAO68bSFBQ&sa=X&oi=book_result&ct=result&res
num=1&ved=0CBMQ6AEwAA#v=onepage&q&f=false
It looks like his particle size is around 10 microns and
that he labels the Si and Co peaks (he assumes the Zn is a product)
Is that how others read it?
So could his catalyst additives be Si and Co?
Dennis Cravens
Those "peaks" marked Si and Co look negligible.
Very surprising there is no indication of copper! Sentence [0068]
says FIGS. 3 and 4 are from points in FIG. 2. Sentence [0066]
says the powder shown in FIG. 2 was withdrawn from the device,
indicating it is an "after" picture. Sentence [0065] seems to
confirm this by saying the FIGS. 2-5 demonstrate that the device
actually provides true nuclear fusion (even though there is no FIG.
5). Should the annotation "Co" have been "Cu"??
Sentence [0069] says zinc is formed, and was not present in the
original powder. Sentence [0071] says after energy generation the
used powders contained Cu, S, Cl, K, and Ca. This list is
mysterious. As I showed earlier, energetically feasible fusion-
fission reactions for H+Ni can produce He, C, O, Si, S, Ti, Cr, Co,
Cu, and Zn. Combined with a weak sub-reaction of the form
p + e --> n + antineutrino - 782.353 kEv
additional candidates for creation from Ni are D, T, B, N, Al, P, Sc,
V, Fe, Cu. It is notable that it is not energetically possible to
directly obtain K, Ca, or Cl via a single fusion-fission reaction
from any isotope of Ni, even with weak reactions considered.
It is notable that Cl is readily produced from S, however:
34S16 + p* --> 35Cl17 + 6.371 MeV [00.736 MeV] (H_S:1)
34S16 + 2 p* --> 35Cl17 + 1H1 + 6.371 MeV [-5.491 MeV] (H_S:3)
36S16 + p* --> 37Cl17 + 8.386 MeV [2.855 MeV] (H_S:5)
36S16 + 2 p* --> 37Cl17 + 1H1 + 8.386 MeV [-3.264 MeV] (H_S:8)
Ca and K and Cl are not produced directly from a strong H + X
reaction until Se, but then many other elements not identified are
also created in greater abundances. Ca and K seem to be a difficult
element to create by fusion-fission. Yittrium, niobium, or
molybdenum, or various other heavier elements with hydrogen create S,
Ti, K, Ca, and CL, but also a lot of other elements not mentioned.
Cs + H very notably creates a lot of Ca and Kr, and little else. Cs
+ H with a weak reaction can create a lot of K. Here is a candidate
reaction:
133Cs55 + p* --> 86Kr36 + 48Ca20 + 46.698 MeV [34.316 MeV] (H_Cs:1)
The Kr gas would be difficult to detect. One is left to speculate
that 133Cs55, possibly with trace amounts of the radioactive 134Cs55
or 137Cs55 is one of the additional magic ingredients. With 1.229
and 2.059 MeV decay energies, the radioactive 134Cs spectrum might
be readily recognized.
Again, just speculation.
Best regards,
Horace Heffner
http://www.mtaonline.net/~hheffner/
