How many times has the Pons-Fleischmann Anomalous Heating Event been replicated in peer reviewed journals?

How does this help me find my missing socks?

Of all the bizarre, poorly formatted, migraine-inducing posts I have seen on FR in the past 20 years, this one takes the cake.

I didn’t catch all of that. Could you repeat it?

Is there an executive summary (fewer than 100,000 words) ?

ML/NJ

The answer to the question is “more than 153 times”. Probably hundreds of times by now.

Not lookin at all that mess

https://freerepublic.com/focus/chat/3967006/posts?page=9#9

To: plain talk
Buried in the 1st presentation (google) is this statement —
“There is a heated debate in the LENR community about the degree to which anomalous effects are already “proven”.
Our experience is the LENR community either can not teach or will not teach. Failure to share the best of what is known has impeded scientific progress.”

9 posted on 6/11/2021, 11:07:50 AM by plain talk
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To: plain talk
Funny enough, we haven’t heard from the Google Team until 2-3 years after they had already shut down. They also tack on the bullshiite term “truly independent replication” and “reasonable” replication by “qualified experts”. They are all over the map on this thing.
They were obviously paranoid about what this would do to their careers.
How many times has the Pons-Fleischmann Anomalous Heating Event been replicated in peer reviewed journals?
https://freerepublic.com/focus/f-chat/3963819/posts

11 posted on 6/11/2021, 11:12:20 AM by Kevmo (some things may be true even if Donald Trump said them. ~Jonathan Karl)
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Jed Rothwell wrote upthread:

Hot fusion skeptics who rarely if ever use calorimetry in their physics profession failed to replicate P&F. They proceeded from that to say that it was proof that LENR wasn’t real.

Actually, to be a little more historically accurate, they did not try to replicate P&F. They tried to replicate one aspect of P&F, which unfortunately, P&F themselves got wrong.

What they did in most cases was: set up an electrochemical cell with a palladium cathode and heavy water, and then look for neutrons. They did not look for excess heat, and they did not measure some critical parameters such as loading.

P&F reported neutrons, but most people soon concluded that part of their paper was wrong. Fleischmann himself thought it was a mistake. He told me that in person, at MIT.

Excess heat is the most critical parameter. It is the “principal signature of the reaction” as Fleischmann put it. If you don’t see excess heat, you don’t have cold fusion, so there is no point to looking for anything else. It is like fishing in a dry hole, as Ikegami put it.

The other mistake made by many hot fusion and high energy physicists was to do the experiment without consulting with electrochemists. They made many mistakes. Enough to eliminate any chance of success.

As I put it, they were trying to tune a piano with sledge hammer.

See p. 11: http://lenr-canr.org/acrobat/RothwellJlessonsfro.pdf

Electrochemists who reviewed other experiments discovered similar errors, such as confusing the anode and the cathode. I suppose that if a group of electrochemists were to try to build a Tokomak plasma fusion reactor without consulting with plasma physicists, they would make similar mistakes.

Using the 'pre' tag for 'preserving' formatting spaces

 


List 2. Peer-reviewed excess heat papers, from both databases
1. Agelao, G. and M.C. Romano, Heat and helium production during exothermic reactions
between gases through palladium geometrical elements loaded with hydrogen. Fusion
Technol., 2000. 38: p. 224.
2. Aoki, T., et al., Search for nuclear products of the D + D nuclear fusion. Int. J. Soc. Mat.
Eng. Resources, 1998. 6(1): p. 22.
3. Arata, Y. and Y.C. Zhang, Achievement of intense 'cold fusion' reaction. Kaku Yugo
Kenkyu, 1989. 62: p. 398 (In Japanese).
4. Arata, Y. and Y.C. Zhang, Achievement of an intense cold fusion reaction. Fusion
Technol., 1990. 18: p. 95.
5. Arata, Y. and Y.C. Zhang, Achievement of intense 'cold' fusion reaction. Proc. Jpn. Acad.,
Ser. B, 1990. 66: p. 1.
6. Arata, Y. and Y.C. Zhang, Corroborating evidence for 'cold' fusion reaction. Proc. Jpn.
Acad., Ser. B, 1990. 66(B): p. 110.
7. Arata, Y. and Y.C. Zhang, 'Cold' fusion caused by a weak 'on-off effect'. Proc. Jpn. Acad.,
Ser. B, 1992. 66: p. 33.
8. Arata, Y. and Y.C. Zhang, 'Cold' fusion in deuterated complex cathode. Kaku Yugo
Kenkyu, 1992. 67((5)): p. 432 (in Japanese).
9. Arata, Y. and Y.C. Zhang, Reproducible "Cold" Fusion Reaction Using A Complex
Cathode. Fusion Technol., 1992. 22: p. 287.
10. Arata, Y. and Y.C. Zhang, Excess heat in a double structure deuterated cathode. Kaku
Yugo Kenkyu, 1993. 69((8)): p. 963 (in Japanese).
11. Arata, Y. and Y.C. Zhang, A new energy caused by "Spillover-deuterium". Proc. Jpn.
Acad., Ser. B, 1994. 70 ser. B: p. 106.
12. Arata, Y. and Y.C. Zhang, A new energy generated in DS-cathode with 'Pd-black'. Koon
Gakkaishi, 1994. 20(4): p. 148 (in Japanese).
13. Arata, Y. and Y.C. Zhang, Achievement of solid-state plasma fusion ("cold fusion").
Koon Gakkaishi, 1995. 21((6)): p. 303 (in Japanese).
14. Arata, Y. and Y.C. Zhang, Deuterium nuclear reaction process within solid. Proc. Jpn.
Acad., Ser. B, 1996. 72 Ser. B: p. 179.
15. Arata, Y. and C. Zhang, Presence of helium (4/2He, 3/2He) confirmed in highly
deuterated Pd-black by the new detecting methodology. J. High Temp. Soc., 1997. 23: p.
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Production from Highly Deuterated Fine Particles. Jpn. J. Appl. Phys. Part 2, 1999. 38: p.
L774.
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Nuclear Fusion. Proc. Jpn. Acad., Ser. B, 2002. 78(Ser. B): p. 57.
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19
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20
41. Focardi, S., et al., Large excess heat production in Ni-H systems. Nuovo Cimento Soc.
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50. Iyengar, P.K., et al., Bhabha Atomic Research Centre studies on cold fusion. Fusion
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52. Kainthla, R.C., et al., Sporadic observation of the Fleischmann-Pons heat effect.
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56. Karabut, A.B., Y.R. Kucherov, and I.B. Savvatimova, Nuclear reactions at the cathode in
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57. Karabut, A.B., Y.R. Kucherov, and I.B. Savvatimova, The investigation of deuterium
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58. Kirkinskii, V.A., V.A. Drebushchak, and A.I. Khmelnikov, Excess heat release during
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59. Kunimatsu, K., Current status of room-temperature nuclear fusion. Excess heat
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61. Lewis, D. and K. Sk'ld, A phenomenological study of the Fleischmann-Pons effect. J.
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21
62. Lewis, D., Some regularities and coincidences in thermal, electrochemical and radiation
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22
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23
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