According to Jed Rothwell
The first ~100 replications came in from a veritable Who's Who of electrochemistry.
https://www.mail-archive.com/v…@eskimo.com/msg82379.html
Where are all those replication reports?
According to Jed Rothwell
The first ~100 replications came in from a veritable Who's Who of electrochemistry.
https://www.mail-archive.com/v…@eskimo.com/msg82379.html
Where are all those replication reports?
http://lenr-canr.org/acrobat/RothwellJtallyofcol.pdf
See also Table 2 in Storms, "Science Of Low Energy Nuclear Reaction"
Jed, that Britz paper just tallies how many there are but it does not list them.
Do we have to buy Storms's book in order to see that Table 2.
Ok, I see. It's Appendix A, List 2 of Jed's tallies. 153 documented peer reviewed Excess Heat findings.
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.
110 (in Japanese).
16. Arata, Y. and Y.C. Zhang, Solid-state plasma fusion ('cold fusion'). J. High Temp. Soc.,
1997. 23 (special volume): p. 1-56.
17. Arata, Y. and Y.C. Zhang, Observation of Anomalous Heat Release and Helium-4
Production from Highly Deuterated Fine Particles. Jpn. J. Appl. Phys. Part 2, 1999. 38: p.
L774.
18. Arata, Y. and Y.C. Zhang, Formation of Condensed Metallic Deuterium Lattice and
Nuclear Fusion. Proc. Jpn. Acad., Ser. B, 2002. 78(Ser. B): p. 57.
19. Arata, Y. and Y. Zhang, The Establishment of Solid Nuclear Fusion Reactor. J. High
Temp. Soc., 2008. 34(2): p. 85.
20. Babu, K.S.C., et al., On the formation of palladium deuteride and its relationship to
suspected cold fusion. Adv. Hydrogen Energy, 1990. 8 Hydrogen Energy Prog. VIII,
Vol. 2),: p. 1051.
19
21. Battaglia, A., et al., Neutron emission in Ni-H systems. Nuovo Cimento Soc. Ital. Fis. A,
1999. 112 A: p. 921.
22. Belzner, A., et al., Two fast mixed-conductor systems: deuterium and hydrogen in
palladium - thermal measurements and experimental considerations. J. Fusion Energy,
1990. 9(2): p. 219.
23. Belzner, A., et al., Recent results on mixed conductors containing hydrogen or deuterium.
Solid State Ionics, 1990. 40/41: p. 519.
24. Bertalot, L., et al., Study of deuterium charging in palladium by the electrolysis of heavy
water: heat excess production. Nuovo Cimento Soc. Ital. Fis. A, 1993. 15 D: p. 1435.
25. Birgul, O., et al., Electrochemically induced fusion of deuterium using surface modified
palladium electrodes. J. Eng. Env. Sci., 1990. 14(3): p. 373.
26. Brudanin, V.B., et al., Search for the cold fusion d(d,(4)He) in electrolysis of D2O. Phys.
Lett. A, 1990. 151(9): p. 543.
27. Bush, B.F., et al., Helium production during the electrolysis of D2O in cold fusion
experiments. J. Electroanal. Chem., 1991. 304: p. 271.
28. Bush, R.T., A light water excess heat reaction suggests that 'cold fusion' may be 'alkalihydrogen
fusion'. Fusion Technol., 1992. 22: p. 301.
29. Bush, R.T. and R.D. Eagleton, Evidence for Electrolytically Induced Transmutation and
Radioactivity Correlated with Excess Heat in Electrolytic Cells with Light Water
Rubidium Salt Electrolytes. Trans. Fusion Technol., 1994. 26(4T): p. 334.
30. Celani, F., et al., Deuterium overloading of palladium wires by means of high power
microsecond pulsed electrolysis and electromigration: suggestions of a "phase
transition" and related excess heat. Phys. Lett. A, 1996. 214: p. 1.
31. Celani, F., et al., Reproducible D/Pd ratio > 1 and excess heat correlation by 1-microsecpulse,
high-current electrolysis. Fusion Technol., 1996. 29: p. 398.
32. Dash, J., G. Noble, and D. Diman, Surface Morphology and Microcomposition of
Palladium Cathodes After Electrolysis in Acified Light and Heavy Water: Correlation
With Excess Heat. Trans. Fusion Technol., 1994. 26(4T): p. 299.
33. Dufour, J., Cold fusion by sparking in hydrogen isotopes. Fusion Technol., 1993. 24: p.
205.
34. Dufour, J., et al., Interaction of palladium/hydrogen and palladium/deuterium to measure
the excess energy per atom for each isotope. Fusion Technol., 1997. 31: p. 198.
35. Fleischmann, M., S. Pons, and M. Hawkins, Electrochemically induced nuclear fusion of
deuterium. J. Electroanal. Chem., 1989. 261: p. 301 and errata in Vol. 263.
36. Fleischmann, M., et al., Calorimetry of the palladium-deuterium-heavy water system. J.
Electroanal. Chem., 1990. 287: p. 293.
37. Fleischmann, M. and S. Pons, Some comments on the paper Analysis of experiments on
the calorimetry of LiOD-D2O electrochemical cells, R.H. Wilson et al., J. Electroanal.
Chem. 332 [1992] 1. J. Electroanal. Chem., 1992. 332: p. 33.
38. Fleischmann, M. and S. Pons, Calorimetry of the Pd-D2O system: from simplicity via
complications to simplicity. Phys. Lett. A, 1993. 176: p. 118.
39. Fleischmann, M. and S. Pons, Reply to the critique by Morrison entitled 'Comments on
claims of excess enthalpy by Fleischmann and Pons using simple cells made to boil. Phys.
Lett. A, 1994. 187: p. 276.
40. Focardi, S., R. Habel, and F. Piantelli, Anomalous heat production in Ni-H systems.
Nuovo Cimento Soc. Ital. Fis. A, 1994. 107A: p. 163.
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41. Focardi, S., et al., Large excess heat production in Ni-H systems. Nuovo Cimento Soc.
Ital. Fis. A, 1998. 111A: p. 1233.
42. Gozzi, D., et al., Evidences for associated heat generation and nuclear products release
in palladium heavy-water electrolysis. Nuovo Cimento Soc. Ital. Fis. A, 1990. 103: p.
143.
43. Gozzi, D., et al., Nuclear and thermal effects during electrolytic reduction of deuterium
at palladium cathode. J. Fusion Energy, 1990. 9(3): p. 241.
44. Gozzi, D., et al., Calorimetric and nuclear byproduct measurements in electrochemical
confinement of deuterium in palladium. J. Electroanal. Chem., 1995. 380: p. 91.
45. Gozzi, D., et al., Quantitative measurements of helium-4 in the gas phase of Pd + D2O
electrolysis. J. Electroanal. Chem., 1995. 380: p. 109.
46. Gozzi, D., et al., X-ray, heat excess and 4He in the D/Pd system. J. Electroanal. Chem.,
1998. 452: p. 251.
47. Isagawa, S., Y. Kanda, and T. Suzuki, Present status of cold fusion experiment at KEK".
Int. J. Soc. Mat. Eng. Resources, 1998. 65(1): p. 60.
48. Isobe, Y., et al., Search for multibody nuclear reactions in metal deuteride induced with
ion beam and electrolysis methods. Jpn. J. Appl. Phys. A, 2002. 41(part 1): p. 1546.
49. Iwamura, Y., et al., Detection of anomalous elements, x-ray, and excess heat in a D2-Pd
system and its interpretation by the electron-induced nuclear reaction model. Fusion
Technol., 1998. 33: p. 476.
50. Iyengar, P.K., et al., Bhabha Atomic Research Centre studies on cold fusion. Fusion
Technol., 1990. 18: p. 32.
51. Kainthla, R.C., et al., Eight chemical explanations of the Fleischmann-Pons effect. J.
Hydrogen Energy, 1989. 14(11): p. 771.
52. Kainthla, R.C., et al., Sporadic observation of the Fleischmann-Pons heat effect.
Electrochim. Acta, 1989. 34: p. 1315.
53. Kamada, K., H. Kinoshita, and H. Takahashi, Anomalous heat evolution of deuteriumimplanted
Al upon electron bombardment. Jpn. J. Appl. Phys. A, 1996. 35: p. 738.
54. Kamada, K., Heating of deuteron implanted Al on electron bombardment and its possible
relation to 'cold fusion' experiment. Fusion Eng. Des., 2001. 55: p. 541.
55. Karabut, A.B., Y.R. Kucherov, and I.B. Savvatimova. Cold Fusion Observation at GasDischarge
Device Cathode. in Anniversary Specialist Conf. on Nucl. Power Eng. in
Space. 1990. Obninsk, Russia.
56. Karabut, A.B., Y.R. Kucherov, and I.B. Savvatimova, Nuclear reactions at the cathode in
a gas discharge. Sov. Tech. Phys. Lett., 1990. 16(6): p. 463.
57. Karabut, A.B., Y.R. Kucherov, and I.B. Savvatimova, The investigation of deuterium
nuclei fusion at glow discharge cathode. Fusion Technol., 1991. 20: p. 924.
58. Kirkinskii, V.A., V.A. Drebushchak, and A.I. Khmelnikov, Excess heat release during
deuterium sorption-desorption by finely powdered palladium deuteride. Europhys. Lett.,
2002. 58: p. 462.
59. Kunimatsu, K., Current status of room-temperature nuclear fusion. Excess heat
measurement. Petrotech. (Tokyo), 1994. 17(12): p. 998 (in Japanese).
60. Kunimatsu, K., Surface modification of the cathode in the study of cold fusion. Hyomen
Gijutsu, 1996. 47(3): p. 218 (in Japanese).
61. Lewis, D. and K. Sk'ld, A phenomenological study of the Fleischmann-Pons effect. J.
Electroanal. Chem., 1990. 294: p. 275.
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62. Lewis, D., Some regularities and coincidences in thermal, electrochemical and radiation
phenomena observed in experiments at Studsvik on the Fleischmann-Pons effect. J.
Electroanal. Chem., 1991. 316: p. 353.
63. Li, X.Z., A new approach towards nuclear fusion without strong nuclear radiation. Nucl.
Fusion Plasma Phys., 1996. 16(2): p. 1 (in Chinese).
64. Li, X.Z., et al., Correlation between abnormal deuterium flux and heat flow in a D/Pd
system. J. Phys. D: Appl. Phys., 2003. 36: p. 3095-3097.
65. Liaw, B.Y., et al., Elevated-temperature excess heat production in a Pd + D system. J.
Electroanal. Chem., 1991. 319: p. 161.
66. Liaw, B.Y., P.L. Tao, and B.E. Liebert, Helium analysis of palladium electrodes after
molten salt electrolysis. Fusion Technol., 1993. 23: p. 92.
67. Lin, G.H., et al., On electrochemical tritium production. Int. J. Hydrogen Energy, 1990.
15: p. 537.
68. Lipson, A.G., et al., Generation of the products of DD nuclear fusion in high-temperature
superconductors YBa2Cu3O7-deltaDy near the superconducting phase transition. Tech.
Phys., 1995. 40: p. 839.
69. Lipson, A.G., et al., The nature of excess energy liberated in a Pd/PdO heterostructure
electrochemically saturated with hydrogen (deuterium). Russ. J. Phys. Chem., 1995. 69:
p. 1810.
70. Lyakhov, B.F., et al., Anomalous heat release in the Pd/PdO system electrolytically
saturated with hydrogen. Russ. J. Phys. Chem., 1993. 67: p. 491.
71. Mathews, C.K., et al., On the possibility of nuclear fusion by the electrolysis of heavy
water. Indian J. Technol., 1989. 27: p. 229.
72. McKubre, M.C.H., et al., Isothermal Flow Calorimetric Investigations of the D/Pd and
H/Pd Systems. J. Electroanal. Chem., 1994. 368: p. 55.
73. Mengoli, G., et al., Absorption-desorption of deuterium at Pd95%-Rh5% alloy. I:
Environment and temperature effects. J. Electroanal. Chem., 1995. 390: p. 135.
74. Mengoli, G., et al., Anomalous heat effects correlated with electrochemical hydriding of
nickel. Nuovo Cimento Soc. Ital. Fis. A, 1998. 20 D: p. 331.
75. Mengoli, G., et al., Calorimetry close to the boiling temperature of the D2O/Pd
electrolytic system. J. Electroanal. Chem., 1998. 444: p. 155.
76. Miao, B., Experimental exploration on the possible mechanism of D-D cold fusion in
titanium lattice. Xibei Shifan Xuebao. Ziran Kexueban, 1994. 30(1): p. 39 (in Chinese).
77. Miao, B., Experimental exploration on possible mechanism of D-D cold fusion in
titanium lattice. Xibei Shifan Daxue Xuebao, Ziran Kexueban, 1994. 30: p. 44 (in
Chinese).
78. Miles, M., K.H. Park, and D.E. Stilwell, Electrochemical calorimetric evidence for cold
fusion in the palladium-deuterium system. J. Electroanal. Chem., 1990. 296: p. 241.
79. Miles, M., et al. Heat and Helium Production in Cold Fusion Experiments. in Second
Annual Conference on Cold Fusion, "The Science of Cold Fusion". 1991. Como, Italy:
Societa Italiana di Fisica, Bologna, Italy.
80. Miles, M., et al., Correlation of excess power and helium production during D2O and
H2O electrolysis using palladium cathodes. J. Electroanal. Chem., 1993. 346: p. 99.
81. Miles, M., B.F. Bush, and J.J. Lagowski, Anomalous effects involving excess power,
radiation, and helium production during D2O electrolysis using palladium cathodes.
Fusion Technol., 1994. 25: p. 478.
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82. Miles, M., B.F. Bush, and D.E. Stilwell, Calorimetric principles and problems in
measurements of excess power during Pd-D2O electrolysis. J. Phys. Chem., 1994. 98: p.
1948.
83. Miles, M. and B.F. Bush, Heat and Helium Measurements in Deuterated Palladium.
Trans. Fusion Technol., 1994. 26(4T): p. 156.
84. Miles, M. and B.F. Bush, Heat and Helium Measurements in Deuterated Palladium.
Trans. Fusion Technol., 1994. 26(4T): p. 156.
85. Miles, M., Reply to 'An assessment of claims of excess heat in cold fusion calorimetry'. J.
Phys. Chem. B, 1998. 102: p. 3648.
86. Miles, M., Reply to 'Examination of claims of Miles et al. in Pons-Fleischmann-type cold
fusion experiments'. J. Phys. Chem. B, 1998. 102: p. 3642.
87. Miles, M., Calorimetric studies of Pd/D2O+LiOD electrolysis cells. J. Electroanal.
Chem., 2000. 482: p. 56.
88. Miles, M., M.A. Imam, and M. Fleischmann, Calorimetric analysis of a heavy water
electrolysis experiment using a Pd-B alloy cathode. Proc. Electrochem. Soc., 2001.
2001-23: p. 194.
89. Miles, M., M.A. Imam, and M. Fleischmann, Calorimetric analysis of a heavy water
electrolysis experiment using a Pd-B alloy cathode. Proc. Electrochem. Soc., 2001.
2001-23: p. 194.
90. Miley, G.H., et al., Electrolytic Cell with Multilayer Thin-Film Electrodes. Trans. Fusion
Technol., 1994. 26(4T): p. 313.
91. Mills, R.L. and P. Kneizys, Excess heat production by the electrolysis of an aqueous
potassium carbonate electrolyte and the implications for cold fusion. Fusion Technol.,
1991. 20: p. 65.
92. Mills, R.L., Reply to 'Comments on "Excess heat production by the electrolysis of an
aqueous potassium carbonate electrolyte and the implications for cold fusion"'. Fusion
Technol., 1992. 21: p. 96.
93. Mizuno, T., et al., Anomalous heat evolution from a solid-state electrolyte under
alternating current in high-temperature D2 gas. Fusion Technol., 1996. 29: p. 385.
94. Mizuno, T., et al., Production of Heat During Plasma Electrolysis. Jpn. J. Appl. Phys. A,
2000. 39: p. 6055.
95. Mizuno, T., et al., Hydrogen Evolution by Plasma Electrolysis in Aqueous Solution. Jpn.
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96. Mosier-Boss, P.A. and S. Szpak, The Pd/(n)H system: transport processes and
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97. Nakamura, K., T. Kawase, and I. Ogura, Possibility of element transmutation by arcing in
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98. Noninski, V.C. and C.I. Noninski, Determination of the excess energy obtained during
the electrolysis of heavy water. Fusion Technol., 1991. 19: p. 364.
99. Noninski, V.C., Excess heat during the electrolysis of a light water solution of K2CO3
with a nickel cathode. Fusion Technol., 1992. 21: p. 163.
100. Notoya, R., Cold fusion by electrolysis in a light water-potassium carbonate solution
with a nickel electrode. Fusion Technol., 1993. 24: p. 202.
101. Notoya, R., Y. Noya, and T. Ohnishi, Tritium generation and large excess heat evolution
by electrolysis in light and heavy water-potassium carbonate solutions with nickel
electrodes. Fusion Technol., 1994. 26: p. 179.
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102. Numata, H. and M. Fukuhara, Low-temperature elastic anomalies and heat generation of
deuterated palladium. Fusion Technol., 1997. 31: p. 300.
103. Ohmori, T. and M. Enyo, Excess heat evolution during electrolysis of H2O with nickel,
gold, silver, and tin cathodes. Fusion Technol., 1993. 24: p. 293.
104. Ohmori, T. and T. Mizuno, Nuclear transmutation occurring in the electrolysis on
several metal electrodes. Curr. Topics Electrochem., 1997. 5: p. 37.
105. Ohmori, T., et al., Transmutation in the electrolysis of lightwater - excess energy and
iron production in a gold electrode. Fusion Technol., 1997. 31: p. 210.
106. Ohmori, T., et al., Transmutation in a gold-light water electrolysis system. Fusion
Technol., 1998. 33: p. 367.
107. Okamoto, M., et al., Excess Heat Generation, Voltage Deviation, and Neutron Emission
in D2O-LiOD Systems. Trans. Fusion Technol., 1994. 26(4T): p. 176.
108. Okamoto, M., et al., Excess Heat Generation, Voltage Deviation, and Neutron Emission
in D2O-LiOD Systems. Trans. Fusion Technol., 1994. 26(4T): p. 176.
109. Oriani, R.A., et al., Calorimetric measurements of excess power output during the
cathodic charging of deuterium into palladium. Fusion Technol., 1990. 18: p. 652.
110. Oriani, R.A., An investigation of anomalous thermal power generation from a protonconducting
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111. Ota, K., H. Yoshitake, and N. Kamiya, Present status of cold fusion. Hyomen Kagaku,
1993. 14(9): p. 570 (in Japanese).
112. Ota, K. and T. Kobayashi, Cold fusion and calorimetry. Netsu Sokutei, 1997. 24(3): p.
138 (Japan., Engl. abstr.).
113. Ota, K., et al., Effect of boron for the heat production during the heavy water electrolysis
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114. Oyama, N., et al., Electrochemical calorimetry of D2O electrolysis using a palladium
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115. Oyama, N., et al., Probing absorption of deuterium into palladium cathodes during D2O
electrolysis with an in situ electrochemical microbalance technique. Jpn. J. Appl. Phys.
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116. Oyama, N. and O. Hatozaki, Present and future of cold fusion - nuclear fusion induced by
electrochemical reaction. Oyo Butsuri, 1991. 60: p. 220 (in Japanese).
117. Pons, S. and M. Fleischmann, Calorimetric measurements of the palladium/deuterium
system: fact and fiction. Fusion Technol., 1990. 17: p. 669.
118. Pons, S. and M. Fleischmann, Etalonnage du systeme Pd-D2O: effets de protocole et
feed-back positif. ["Calibration of the Pd-D2O system: protocol and positive feed-back
effects"]. J. Chim. Phys., 1996. 93: p. 711 (in French).
119. Preparata, G., M. Scorletti, and M. Verpelli, Isoperibolic calorimetry on modified
Fleischmann-Pons cells. J. Electroanal. Chem., 1996. 411: p. 9.
120. Ray, M.K.S., et al., The Fleischmann-Pons phenomenon - a different perspective. Fusion
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121. Santhanam, K.S.V., et al., Electrochemically initiated cold fusion of deuterium. Indian J.
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122. Santhanam, K.S.V., et al., Excess enthalpy during electrolysis of D2O. Curr. Sci., 1989.
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123. Savvatimova, I. and A.B. Karabut, Nuclear reaction products detected at the cathode
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124. Savvatimova, I. and A.B. Karabut, Radioactivity of palladium cathodes after irradiation
in a glow discharge. Poverkhnost, 1996(1): p. 76 (in Russian).
125. Scott, C.D., et al., Measurement of excess heat and apparent coincident increases in the
neutron and gamma-ray count rates during the electrolysis of heavy water. Fusion
Technol., 1990. 18: p. 103.
126. Scott, C.D., et al., Preliminary Investigation of Possible Low-Temperature Fusion. J.
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127. Shirai, O., et al., Some experimental results relating to cold nuclear fusion. Bull. Inst.
Chem. Res., Kyoto Univ., 1991. 69: p. 550.
128. Srinivasan, M., Nuclear fusion in an atomic lattice: An update on the international status
of cold fusion research. Curr. Sci., 1991. 60: p. 417.
129. Storms, E., Measurements of excess heat from a Pons-Fleischmann-type electrolytic cell
using palladium sheet. Fusion Technol., 1993. 23: p. 230.
130. Storms, E., Some Characteristics of Heat Production Using the "Cold Fusion" Effect.
Trans. Fusion Technol., 1994. 26(4T): p. 96.
131. Storms, E., How to produce the Pons-Fleischmann effect. Fusion Technol., 1996. 29: p.
261.
132. Swartz, M.R., Codeposition of palladium and deuterium. Fusion Technol., 1997. 32: p.
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133. Swartz, M.R., Consistency of the biphasic nature of excess enthalpy in solid-state
anomalous phenomena with the quasi-one-dimensional model of isotope loading into a
material. Fusion Technol., 1997. 31: p. 63.
134. Szpak, S., et al., Electrochemical charging of Pd rods. J. Electroanal. Chem., 1991. 309:
p. 273.
135. Szpak, S., P.A. Mosier-Boss, and J.J. Smith, On the behavior of Pd deposited in the
presence of evolving deuterium. J. Electroanal. Chem., 1991. 302: p. 255.
136. Szpak, S., P.A. Mosier-Boss, and S.R. Scharber, Charging of the Pd/(n)H system: role of
the interphase. J. Electroanal. Chem., 1992. 337: p. 147.
137. Szpak, S., et al., Cyclic voltammetry of Pd + D codeposition. J. Electroanal. Chem., 1995.
380: p. 1.
138. Szpak, S. and P.A. Mosier-Boss, Nuclear and Thermal Events Associated with Pd + D
Codeposition. J. New Energy, 1996. 1(3): p. 54.
139. Szpak, S. and P.A. Mosier-Boss, On the behavior of the cathodically polarized Pd/D
system: a response to Vigier's comments. Phys. Lett. A, 1996. 221: p. 141.
140. Szpak, S., P.A. Mosier-Boss, and J.J. Smith, On the behavior of the cathodically
polarized Pd/D system: Search for emanating radiation. Phys. Lett. A, 1996. 210: p. 382.
141. Szpak, S., et al., On the behavior of the Pd/D system: Evidence for tritium production.
Fusion Technol., 1998. 33: p. 38.
142. Szpak, S. and P.A. Mosier-Boss, On the release of n/1H from cathodically polarized
palladium electrodes. Fusion Technol., 1998. 34: p. 273.
143. Szpak, S., P.A. Mosier-Boss, and M. Miles, Calorimetry of the Pd+D codeposition.
Fusion Technol., 1999. 36: p. 234.
144. Szpak, S., et al., Thermal behavior of polarized Pd/D electrodes prepared by codeposition.
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145. Szpak, S., et al., Evidence of nuclear reactions in the Pd lattice. Naturwiss., 2005. 92(8):
p. 394-397.
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146. Takahashi, A., et al., Excess heat and nuclear products by D2O/Pd electrolysis and
multibody fusion. Int. J. Appl. Electromagn. Mater., 1992. 3: p. 221.
147. Takahashi, A., Cold fusion research: present status. Koon Gakkaishi, 1993. 19(5): p. 179
(in Japanese).
148. Takahashi, A., Production of neutron, tritium and excess heat. Oyo Butsuri, 1993. 62: p.
707 (In Japanese).
149. Takahashi, A., et al., Experimental study on correlation between excess heat and nuclear
products by D2O/Pd electrolysis. Int. J. Soc. Mat. Eng. Resources, 1998. 6(1): p. 4.
150. Velev, O.A. and R.C. Kainthla, Heat flow calorimeter with a personal-computer-based
data acquisition system. Fusion Technol., 1990. 18: p. 351.
151. Yun, K.S., et al., Calorimetric observation of heat production during electrolysis of 0.1
M LiOD + D2O solution. J. Electroanal. Chem., 1991. 306: p. 279.
152. Zhang, Q., et al., The excess heat experiments on cold fusion in titanium lattice. Chin. J.
and for those , not just failing to reproduce, but proposing an explanation in an article that was published (some got published in surprising way, and some were not retracted in surprising way), 4 articles.
Kirk Shanahan battle to make the 5th published.
Beaudette summarize the story:
Unfortunately, physicists did not generally claim expertise in calorimetry, the measurement of calories of heat energy. Nor did they countenance clever chemists declaring hypotheses about nuclear physics. Their outspoken commentary largely ignored the heat measurements along with the offer of an hypothesis about unknown nuclear processes. They did not acquaint themselves with the laboratory procedures that produced anomalous heat data. These attitudes held firm throughout the first decade, causing a sustained controversy.
The upshot of this conflict was that the scientific community failed to give anomalous heat the evaluation that was its due. Scientists of orthodox views, in the first six years of this episode, produced only four critical reviews of the two chemists’ calorimetry work. The first report came in 1989 (N. S. Lewis). It dismissed the Utah claim for anomalous power on grounds of faulty laboratory technique. A second review was produced in 1991 (W. N. Hansen) that strongly supported the claim. It was based on an independent analysis of cell data that was provided by the two chemists. An extensive review completed in 1992 (R. H. Wilson) was highly critical though not conclusive. But it did recognize the existence of anomalous power, which carried the implication that the Lewis dismissal was mistaken. A fourth review was produced in 1994 (D. R. O. Morrison) which was itself unsatisfactory. It was rebutted strongly to the point of dismissal and correctly in my view. No defense was offered against the rebuttal. During those first six years, the community of orthodox scientists produced no report of a flaw in the heat measurements that was subsequently sustained by other reports.
The community of scientists at large never saw or knew about this minimalist critique of the claim. It was buried in the avalanche of skepticism that issued forth in the first three months. This skepticism was buttressed by the failure of the two chemists’ nuclear measurements, the lack of a theoretical understanding of how their claim could work, a mistaken concern with the number of failed experiments, a wholly unrealistic expectation of the time and resource the evaluation would need, and the substantial ad hominem attacks on them. However, their original claim of measurement of the anomalous power remained unscathed during all of this furor. A decade later, it was not generally realized that this claim remained essentially unevaluated by the scientific community. Confusion necessarily arose when the skeptics refused without argument to recognize the heat measurement and its corresponding hypothesis of a nuclear source. As a consequence, the story of the excess heat phenomenon has never been told.
Few people realize how weak is the consensus.
Consensus exploit mostly failures by people whose competence don't apply (physicists) to the experiment.
They exploit failures in a reverted Poperian logic.
They ignore refutation of proposed explanation.
They ignore the weak number and weak quality of the refutations.
They ignore reference experimenters who confirmed the results.
They ignore well known problems experience daily in material science.
In a way for someone experience in history of science, in epistemology, in semi-conductors, they are incredibly naive and uneducated, and incredibly tolerant with incompetence and fraud when on their side.
In fact the fallacy at the core of LENR denial is the reverted poperian logic, that things cannot happen if they have no theory.
If you get that fallacy as true, then LENR was falsified because every theory was refuted, theory that it was easy , that just electrolysis was enough, that it was hot fusion in a jar, and all pet theories,
This reverted logic is core to today's pathology of science, who prefer unproven coherent theories, refuted numerical models, unrefutable infinitely tunable models, to uncertain experimental results and unexplained anomalies.
We are back at a dogmatic age.
Sincerely, Galileo was more respected scientifically than today's experimenters without (official) theory, and got home-arrested only for having insulted the Pope (who did not let his executors burn him)... Today, not only science is politicized, but even when not politic, there is dogma you cannot challenge even with data.
Even LENR community suffer from that fallacy with pet theory meditations more popular than old experimenters intuitions.
@kevm
Since Alain mentioned me, but seems a bit confused in what he said, let me try to clarify.
As background, at this point I have published 4 papers relating to CF. The first was about the reanalysis of cold fusion data collected by Dr. Edmund Storms that was posted to the Internet in Feb. 2000. He subsequently presented his interpretation at ICCF8 as showing excess heat. The exciting point in it was that the cathode and anode both were platinum (i.e. no palladium in the system). He obtained excess power signals most of the time when he applied a stepwise increasing to maximum then decreasing to 0 input current. I obtained the data and examined the question of how one could assume there was no excess power actually present, yet obtain the published results. What I found was that a trivial (2-3%) change in calibration constants zeroed out the excess power signals (the maximum size claimed by Storms was 780 mW). My paper was published in 2002. In it I also gave a proposed explanation of what was going on that required no LENRs.
In 2004 Szpak, Mosier-Boss, Miles, and Fleischmann published a paper claiming what I said was in error and made no sense. I rebutted that in 2005. In 2006, Ed Storms published a Comment on my 2002 paper, and I rebutted that in a paper published immediately following Storms’ paper. In 2009, Jan Marwan and Steven Krivit published a pro-CF article, which I published a Comment on in 2010. A group of 10 CF authors published an attempted rebuttal of my comments/proposals, but they screwed it up so badly it’s embarrassing. However, I was not allowed to publish a reply to their comment. I eventually released a whitepaper that contained what I would have written, plus a comment on the calorimetric method F&P used, plus another manuscript that wasn’t allowed to be published responding to some claims by Kitamura, et al, in Phys. Lett A.
I have also been active on the Internet ‘promoting’ my views, including trying to edit the Wikipedia page on CF.
Recently, Krivit misrepresented an email I sent him in answer to a question he asked me. Also, Miles published an article in vol 132 of Infinite Energy, wherein he says he is publishing a paper written primarily by Fleischmann in 2003 but not published because of the Szpak 2004 paper, which is extremely similar. Miles precedes the paper with a 1 page note, claiming that Fleishmann rebutted my work, but I responded in this forum showing that no, he didn’t. In fact he makes the same mistakes that he made in the Szpak 2004 version. See Miles-Fleischmann-Szpak-Mossier-Boss Article in IE132 An interesting side note from the discussion we had (email) was that Miles admitted he has never read my papers. I have to wonder how he can know they are ‘wrong’ when he hasn’t. Storms also recently published a new paper that I comment on here: Edmund Storms publish a paper in "Environmental Science: An Indian Journal" : A New Source of Energy using Low-Energy Fusion of Hydrogen
Perhaps the easiest thing to do to catch up is just click on my name and get the list of posts I made. There are only 330 or so of them, and they are grouped into just a few threads so it should be easy to ‘catch up’ (compared to Jed, Alain, etc.).
With respect to excess heat and LENR, I have found no examples of any published calorimetric work that does not have the same basic flaws in it that I noted in my 2002 paper. Therefore, the question of whether excess heat has really been detected or not remains unanswered to this day. The key flaw is that everyone treats the calorimeter/cell as a homogeneous unit when it doesn’t appear to be. This induces an artificial apparent excess power signal via a mathematical problem with how they interpret their temperature data. You can read the original manuscript version of my first paper here: http://lenr-canr.org/acrobat/ShanahanKapossiblec.pdf
This is a thread that goes into a little detail on these issues as well:
[Split] Reconsidering F&P with CCS....
I don’t believe I make any of the mistakes Alain accuses others of, but he seems unable to grasp that. You can read what I write and decide for yourself though.
Hi Kirk. Thank you for your posts, which are appreciated, even when not agreed with. Can I ask a broader question - do you believe in the reality of any of the hundreds of reported LENR phenomena at all? Not just Pd/D, but any?
do you believe in the reality of any of the hundreds of reported LENR phenomena at all? Not just Pd/D, but any?
The problem with answering your question is that the field has become so inclusive of anomalous results that a 'reported LENR phenomena' could be anything. So let me answer you this way - I do not automatically reject LENR claims, but I am very skeptical. This is based on my interaction with the field since 1995. I usually find LTA efforts to define what could be causing the anomalous results, and I usually find aggressively dismissive consideration of skeptical commentary.
As I've said before, I work with almost all the materials people talk about in the LENR field, and if LENR is true, I need to know. It involves my and my coworkers safety. That's why I studied the F&P-type studies. There was enough crude reproduction of results to suggest something real was going on, and I wanted to know what it might be. I believe I figured it out, but it ain't nuclear, and that has led to mass rejection out-of-hand of my views by those who think it is. That's fine I guess. I just hate it when a newb gets caught up in the fantasy of an free energy world, *and* I am dumb enough to believe scientists try to find the truth, so I keep plugging away. My interactions with the field have gone a long way towards disabusing me of the latter belief in fact.
Bring me something that shows at least a little reproducibility and I'll look at it...
So 'not really' then. Or at least, 'ain't seen nuthin yet'. Thank you.
I was that newb, and in some regards I still am. But I like to have the critical viewpoint. Some people like to argue, some learn others just believe. I have never seen you insult someone just educate and clarify based on a careful reading of the data. Sometimes the truth can be ugly, but it should be educational.
I believe I figured it out, but it ain't nuclear, ....
Bring me something that shows at least a little reproducibility and I'll look at it...
There are 153 published peer reviewed replications according to Britz/Jed. It's a good place to start. If you have it figured out then generate a product for us to buy. Even if it is a space heater that is more expensive than using natural gas, it will provoke the next generation to look into it to see if improvements can be made. That seems like such a high duhh factor to me.
There are 153 published peer reviewed replications according to Britz/Jed. It's a good place to start. If you have it figured out then generate a product for us to buy. Even if it is a space heater that is more expensive than using natural gas, it will provoke the next generation to look into it to see if improvements can be made. That seems like such a high duhh factor to me.
Kevin. Kirk's point I believe is that those replications have not proved repeatable and (Kirk claims) many (and the most promising ones) could likely result from a systemic error he has noted that could apply specifically to LENR-type electrochemistry.
I think you can get the wrong idea here if you see a scientific paper as fact from heaven, rather than as a thing to read, read around all the related work, and only then come to a conclusion as to what it really means. Young doctoral candidates, on their initial literature survey, start with the idea that the headline results in each paper they read mean what they superficially say. Each paper appears to be making some crucial and significant new discovery.
It is only after reading 50 or so, and comparing what they say with your own understanding, that you start to generate an internal model of what it all means.
You should view this 150 paper list as a starting point for your own LS here. After having done it you will be in a much better position to decide whether Kirk's point is valid or no, and also (independently) whether this constitutes good evidence of new physics.
You see the problem here; few (certainly not me) have the patience or time to do this for real. Skimming headlines just does not work - as I can confirm here from having looked at just a very few of these papers. But if you have ever done a scientific or engineering LS you will realise this because it is a general truth.
In order to help you a bit I have looked over the list of 153 references that Jed claims are ‘excess heat papers’.
First off, out of the 153 papers (you dropped 153 from your post BTW) only 5 were published after my 2002 paper on the systematic calorimetric error I detected, so none of the other 148 papers is likely to have enough information on their method to tell if their calorimetry is correct or not because they weren’t aware of the problem. One of the 5 post-2002 papers is the one by Szpak, et al (ref#144) that I replied to with my second publication in 2005. There I showed that their results were consistent with a CCS being present.
Since the reception I have received from the CF community has been universally negative, I feel safe in saying that you won’t find any studies to date that contain enough information relevant to the calorimetric method to evaluate the CCS potential. I’d love to be proven wrong on that statement.
Further, there is a classic problem present in the list, namely the mixing of experimental types, many are not even based in calorimetry. For example, my papers deal specifically with F&P-type electrolysis cells, but this list mixes those in with plasma discharge experiments and arcs in water experiments and possibly others. That is a typical CFer (cold fusion researcher or cold fusion engineer (the last as per Gene Mallove)) illegitimate tactic. The idea that LENRs are present is about the only thing that links these divergent experimental setups, and they shouldn’t be linked like this until they are actually shown separately to have LENRs present. That has not been done.
The calorimetric experiments in F&P-type cells is the largest block of related experiments, and that is what my papers address. I point out that in all cases known to me the calorimetric method used the lumped parameter approach that is susceptible to the calibration constant shift (CCS) problem I outline in my papers. It is usually impossible to tell if that problem is relevant, since the CFer authors never give sufficient calibration details and results to allow testing its relevance. Miles is about the only author who does anything along these lines in that he often quotes the standard deviation of his determinations of the ‘heat transfer coefficients’ (which are just the calibration constants of his calibration equation). They typically are about 1% relative standard deviations. I found approximately the same was all that was required to zero out Ed Storms’ 780 mW excess heat signals in his data I reanalyzed. In Storms’ ICCF8 paper on that data, he shows calibration constants obtained by two methods, electrolytic heating and Joule heating, and they differ. He also says he gets different electrolytic calibration results over time, which is consistent with Miles.
So, to eliminate the CCS problem from consideration, a paper should list the calibration equation and specify the variation of the calibration constants over time and/or method and/or anything else that might be relevant. This is universally missing to my knowledge. If they don’t give that info, you can’t tell if their excess heat signals are real or an artifact of the math.
Note that I agree that there is something going on in F&P cells. I proposed a non-nuclear mechanism for what it could be. That has been was attacked by Storms in 2006, but I rebutted his points. The Szpak, et al derogatory comments were non-specific or irrelevant, as were the ones in the Fleischmann version published by Miles in Infinite Energy vol. 132 (2017). I responded to Szpak, et al in 2005, and posted a few comments here about the recent Miles IE132 publication. The upshot is that they don’t rebut my ATER/CCS mechanism.
The other 4 post-2002 papers are Ararta, ref 19; Li, ref 64; Mizuno, ref 95; and Szpak, ref 145. The Arata paper is on the Pd/ZrO2 system, which was replicated by Kitamura, et al, in Phys Lett A, 373 (2009) 3109. That paper was one I attempted to rebut, since it had enough details presented to be able to analyze them, but was not allowed to publish. The manuscript for that rebuttal is in the whitepaper I have previously mentioned. (The whitepaper is supposed to be here: https://docs.google.com/open?id=0B3d7yWtb1doPc3otVGFUNDZKUDQ) My thesis there is that the observations are consistent with known Pd/Zr/ZrO2/H2 chemistry. That would apply to Arata’s paper as well, if enough information had been presented to do so. The Li, et al paper is on D2 permeation through a Pd tube and gives nothing but a single figure claiming abnormal heat flow observation. No details at all to allow one to assess errors, plus it isn’t an F&P-type electrolysis. The Mizuno paper is on plasma electrolysis with a W cathode, also not an F&P type cell. The Szpak 2005 paper seems to have no information in it regarding excess heat except a mention of ‘hot spots’, so I fail to see why it is on the list at all. It only presents SEM/EDX data.
QuoteYou can read the original manuscript version of my first paper here (Possible Calorimetric Error in Heavy Water Electrolysis on Platinum).
Results with palladium are way more reliable. In addition, you cannot fake the thermal artifacts chemically. Bellow is Fleischmann-Pons electrolytic cell ruined and partially molten by heat evolved during thermal runaway, despite it's electrodes are made of massive palladium rod.
when you load Pd with H it swells. Any visible distortion in a picture like that could just be that...
Display MoreKevin. Kirk's point I believe is that those replications have not proved repeatable and (Kirk claims) many (and the most promising ones) could likely result from a systemic error he has noted that could apply specifically to LENR-type electrochemistry.
That's 153 replications he's trying to undo. That's quite the tall order. I doubt his finding is significant enough to do it, or otherwise we would have been hearing more about it these last 15 years.
I think you can get the wrong idea here if you see a scientific paper as fact from heaven,
Do you see Dolly the Sheep as a "fact from heaven"? It's never been replicated. Lots of "facts from heaven" have had only 2 or 3 replications. 153 replications, well that's significant, especially if they're from what Jed calls the "who's who of electrochemistry".
<snip irrelevant stuff>
It is only after reading 50 or so, and comparing what they say with your own understanding, that you start to generate an internal model of what it all means.
Not all of us are PhD scientists with the time on our hadns to read 50 replication papers, even if we did spend time trying to get access to them. Did you see my question about "where are those papers"?
You should view this 150 paper list as a starting point for your own LS here.
What is an LS? You obviously used an acronym in order to save time and effort, and yet here you are going to have to go back and explain it. Not a very efficient usage of your time.
After having done it you will be in a much better position to decide whether Kirk's point is valid or no, and also (independently) whether this constitutes good evidence of new physics.
Kirk wrote 1 paper, right? And yet there are 153 papers that seem to disagree with his stance. Perhaps Kirk should prove how brilliant he is and write his own retort to those 153 papers. There are other papers too, ones that aren't peer reviewed, etc. Kirk should have been a busy man these past 15 years but instead he wants guys like us to do his busywork.
You see the problem here; few (certainly not me) have the patience or time to do this for real. Skimming headlines just does not work - as I can confirm here from having looked at just a very few of these papers. But if you have ever done a scientific or engineering LS you will realise this because it is a general truth.
I obviously haven't done enough engineering LS's to know what the acronym stands for. My impression from reading a bunch of the papers in LENR-CANR library (and asking for more) is that Kirk's hypothesis doesn't stand up. It was basically ignored, as far as I can tell. That makes him not too bright, because if he has the SOLUTION to this LENR thing, he could have generated tons of data, material, money, and interest by selling chemically based space heaters. I would buy one, just to be able to play with it.
Thank you for the link above. It will take time but I will read it. I am glad you post here. I also appreciate your help when questions arise. Other than Rossi I try to keep my ego out of it and just the facts. Others argue to argue but I argue to learn.
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none of the other 148 papers is likely to have enough information on their method to tell if their calorimetry is correct or not because they weren’t aware of the problem.
Then you should write a paper that replicates their setups and induce the error you claim is happening. In the meantime you could be making a MINT selling LENR calorimetric space heaters.
One of the 5 post-2002 papers is the one by Szpak, et al (ref#144) that I replied to with my second publication in 2005. There I showed that their results were consistent with a CCS being present.
You should do it with dozens more. Start with the biggest names on the list. Make a name for yourself.
Since the reception I have received from the CF community has been universally negative, I feel safe in saying that you won’t find any studies to date that contain enough information relevant to the calorimetric method to evaluate the CCS potential. I’d love to be proven wrong on that statement.
I am certain that the journal NATURE would accept your paper and peer review it if you took on all the best replications of LENR and showed your CCS thingamajig explains the data. I have no idea how scientists of such magnitude can be so far off when they're looking at a device generating a COP of 10 or more. In my mind there should be some glaring indications of their mistake.
Further, there is a classic problem present in the list, namely the mixing of experimental types, many are not even based in calorimetry.
Here is where you can add some value to the field, regardless if someone is a LENR 'believer' or not. You can put together a credible list of how many times the Pons-Fleischmann Anomalous Heating Event has been replicated in peer reviewed journals. That is the starting point of investigation and you're saying that even this starting point is flawed. Add some value, whydoncha?
For example, my papers deal specifically with F&P-type electrolysis cells, but this list mixes those in with plasma discharge experiments and arcs in water experiments and possibly others.
That is kinda one indication that this effect is real, if it shows up in other experimental cells than just PdD calorimeters. I gather your hypothesis of error does not apply to the other mixed cells.
That is a typical CFer (cold fusion researcher or cold fusion engineer (the last as per Gene Mallove)) illegitimate tactic. The idea that LENRs are present is about the only thing that links these divergent experimental setups, and they shouldn’t be linked like this until they are actually shown separately to have LENRs present. That has not been done.
That is valuable scientific data that you should publish to the community as a whole. If I had the knowledge and wherewithal, that's what I would be doing. There is gonna be some hungry physicist who's itching to take a crack at those other cells and come up with his own error hypothesis.
The calorimetric experiments in F&P-type cells is the largest block of related experiments, and that is what my papers address. I point out that in all cases known to me the calorimetric method used the lumped parameter approach that is susceptible to the calibration constant shift (CCS) problem I outline in my papers.
Would it be something you could state categorically that the larger the COP, the larger the error and the more expectation we should have had of these experimenters to see their error?
It is usually impossible to tell if that problem is relevant, since the CFer authors never give sufficient calibration details and results to allow testing its relevance.
Then, do it. Make a name for yourself. Be the go-to guy for generating a scientific baseline in LENR explorations.
Miles is about the only author who does anything along these lines in that he often quotes the standard deviation of his determinations of the ‘heat transfer coefficients’ (which are just the calibration constants of his calibration equation). They typically are about 1% relative standard deviations. I found approximately the same was all that was required to zero out Ed Storms’ 780 mW excess heat signals in his data I reanalyzed. In Storms’ ICCF8 paper on that data, he shows calibration constants obtained by two methods, electrolytic heating and Joule heating, and they differ. He also says he gets different electrolytic calibration results over time, which is consistent with Miles.
What does that mean? If you derive a calibration constant by two different methods, how far out of agreement are they expected to be? Or are they expected to be within 6 sigma agreement (which I would highly doubt). If someone gets different electrolytic calibration results over time, does this happen when there is no indication of LENR? If so it could be one of those indications that LENR might be present, assuming there's other indications. Maybe all of this leads to an issue with electrolytic calibration constants, which could be something that gets you nobel prize level recognition.
So, to eliminate the CCS problem from consideration, a paper should list the calibration equation and specify the variation of the calibration constants over time and/or method and/or anything else that might be relevant.
You came out with your hypothesis after all those papers so the onus should be on you to back-apply your approach.
This is universally missing to my knowledge. If they don’t give that info, you can’t tell if their excess heat signals are real or an artifact of the math.
It's your theory so you should take ownership of it. Back-apply your hypothesis to a few of the best replications and someone will take notice.
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Note that I agree that there is something going on in F&P cells.
I agree. And furthermore I have advocated NOT calling it 'Nuclear' but more like something along the lines of "super-chemical heat generation". That way you can sell boxes and not have the NRC regulate your business.
I proposed a non-nuclear mechanism for what it could be. That has been was attacked by Storms in 2006, but I rebutted his points. The Szpak, et al derogatory comments were non-specific or irrelevant, as were the ones in the Fleischmann version published by Miles in Infinite Energy vol. 132 (2017). I responded to Szpak, et al in 2005, and posted a few comments here about the recent Miles IE132 publication. The upshot is that they don’t rebut my ATER/CCS mechanism.
Then set up your own website where you take down every replication using your mechanism. And sell space heaters & electrocalorimeters. There's thousand dollar bills on the ground, just pick them up.
The other 4 post-2002 papers are Ararta, ref 19; Li, ref 64; Mizuno, ref 95; and Szpak, ref 145. The Arata paper is on the Pd/ZrO2 system, which was replicated by Kitamura, et al, in Phys Lett A, 373 (2009) 3109. That paper was one I attempted to rebut, since it had enough details presented to be able to analyze them, but was not allowed to publish. The manuscript for that rebuttal is in the whitepaper I have previously mentioned. (The whitepaper is supposed to be here: https://docs.google.com/open?id=0B3d7yWtb1doPc3otVGFUNDZKUDQ)
You really should set up your own website and have at it with all those replication papers. You'd be doing yourself and everyone else a favor. And you could have a bunch of cash in your pocket also.
My thesis there is that the observations are consistent with known Pd/Zr/ZrO2/H2 chemistry. That would apply to Arata’s paper as well, if enough information had been presented to do so. The Li, et al paper is on D2 permeation through a Pd tube and gives nothing but a single figure claiming abnormal heat flow observation. No details at all to allow one to assess errors, plus it isn’t an F&P-type electrolysis.
Just focus on F&P type electrolysis to begin with and you'll make a name for yourself. The level of heat all these experimentalists claim over months is enough to give you the Nobel prize if you sell just half a dozen space heaters that replicate their results.
The Mizuno paper is on plasma electrolysis with a W cathode, also not an F&P type cell. The Szpak 2005 paper seems to have no information in it regarding excess heat except a mention of ‘hot spots’, so I fail to see why it is on the list at all. It only presents SEM/EDX data.
Set up a website and critique ALL of them. My interest is in generating a trustworthy starting point for further investigation. If, like you say, there's something to this effect, then give us the list of genuine results. And especially, how not to make your CSS error.
An interesting side note from the discussion we had (email) was that Miles admitted he has never read my papers. I have to wonder how he can know they are ‘wrong’ when he hasn’t.
Interestingly enough, I believe it was hyper-critical Jones who said the same thing about LENR papers.
I would encourage you to collect all these incidents and papers into one website where people can go to get their own information. I had my own run-in with Ed Storms. What I would like to see is a relatively lightly refereed forum where guys like you and Ed go at it and we can all see for ourselves who gives the most scientific answers. I suggested the same thing to Ed when he was badmouthing Y.E. Kim but it was Kim who backed away from engaging, to my surprise.