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(
: 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.
: 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.
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.
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.
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.
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. J. Appl. Phys. A, 2005. 44(1A): p. 396-401.
96. Mosier-Boss, P.A. and S. Szpak, The Pd/(n)H system: transport processes and development of thermal instabilities. Nuovo Cimento Soc. Ital. Fis. A, 1999. 112: p. 577.
97. Nakamura, K., T. Kawase, and I. Ogura, Possibility of element transmutation by arcing in water. Kinki Daigaku Genshiryoku Kenkyusho Nenpo, 1996. 33: p. 25 (in Japanese).
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.
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 oxide. Fusion Technol., 1996. 30: p. 281.
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 using palladium cathode. Int. J. Soc. Mat. Eng. Resources, 1998. 6(1): p. 26.
114. Oyama, N., et al., Electrochemical calorimetry of D2O electrolysis using a palladium cathode - an undivided, open cell system -. Bull. Chem. Soc. Japan, 1990. 63: p. 2659.
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. Part 2, 1990. 29(5): p. L818.
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 Technol., 1992. 22: p. 395.
121. Santhanam, K.S.V., et al., Electrochemically initiated cold fusion of deuterium. Indian J. Technol., 1989. 27: p. 175.
122. Santhanam, K.S.V., et al., Excess enthalpy during electrolysis of D2O. Curr. Sci., 1989. 58: p. 1139.
123. Savvatimova, I. and A.B. Karabut, Nuclear reaction products detected at the cathode after a glow discharge in deuterium. Poverkhnost, 1996(1): p. 63 (in Russian).
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. Fusion Energy, 1990. 9(2): p. 115.
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. 126.
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. Thermochim. Acta, 2004. 410: p. 101.
145. Szpak, S., et al., Evidence of nuclear reactions in the Pd lattice. Naturwiss., 2005. 92(8): p. 394-397.
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. At. Mol. Phys., 1995. 12(2): p. 165.
153. Zhang, Q., et al., The experimental study on the 'excess heat' for deuteron absorbed in the lattice of titanium. Chin. J. At. Mol. Phys., 1998. 15: p. 210 (In Chinese)