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Cold fusion cell at the US Navy Space and Naval Warfare Systems Center San Diego (2005)
For other uses, see Cold Fusion (disambiguation).

Cold fusion, sometimes called low energy nuclear reactions (LENR) or condensed matter nuclear science, is a set of effects reported in controversial laboratory experiments at ordinary temperatures and pressures; some researchers claim these effects are caused by nuclear reactions.

In 1989, Martin Fleischmann and Stanley Pons reported producing a tabletop nuclear fusion reaction at the University of Utah.[1] In their press conferences and papers, they reported the observation of anomalous heating ("excess heat") of an electrolytic cell during electrolysis of heavy water using palladium (Pd) electrodes. Lacking an explanation for the source of such heat, they proposed the hypothesis that the heat came from nuclear fusion of deuterium (D). The report of their results raised hopes of a cheap and abundant source of energy.[2] Cold fusion gained a reputation as pathological science after the majority of scientists who attempted the experiment did not replicate the originally reported results. This failure to replicate was explained through experimental or theoretical oversights in the original work and led the follow-up researchers to discount their conclusions.[3]

A review panel organized by the US Department of Energy (DOE) in 1989 did not find the evidence or argument in favor of cold fusion persuasive. In 2004 the US DOE organized another review panel which—like the one in 1989—did not recommend a focused federally-funded program for low energy nuclear reactions, but did recommend that researchers continue to submit articles to scientific journals and apply for research grants from funding agencies.[4] In the meantime, cold fusion researchers have reported additional supporting results in peer-reviewed journals[5] and at conferences.[6][7]

History[edit]

Early work[edit]

The special ability of palladium to absorb hydrogen was recognized as early as the nineteenth century by Thomas Graham.[8] In the late nineteen-twenties, two German scientists, Friedrich Paneth and K. Peters, reported the transformation of hydrogen into helium by spontaneous nuclear catalysis when hydrogen was absorbed by finely divided palladium at room temperature.[8] These authors later acknowledged that the helium they measured was due to background from the air.

In 1927, Swedish scientist J. Tandberg stated that he had fused hydrogen into helium in an electrolytic cell with palladium electrodes.[8] On the basis of his work, he applied for a Swedish patent for "a method to produce helium and useful reaction energy". After deuterium was discovered in 1932, Tandberg continued his experiments with heavy water. Due to Paneth and Peters' retraction, Tandberg's patent application was eventually denied.[8]

The term "cold fusion" was coined by Dr. E. Paul Palmer of Brigham Young University in 1986 in an investigation of "geo-fusion", or the possible existence of fusion in a planetary core.[9]

Fleischmann-Pons announcement[edit]

Fleischmann said that he began investigating the possibility that chemical means could influence nuclear processes in the 1960s.[10] He said that he explored whether collective effects, that would require quantum electrodynamics to calculate, might be more significant than the effects predicted by quantum mechanical calculations.[11][12][13] He said that, by 1983, he had experimental evidence leading him to believe that condensed phase systems developed coherent structures up to 10-7m in size.[12] In 1984, Fleischmann and Pons began cold fusion experiments.[14] In 1985, they informally reported that one of their experiments resulted in the melting and partial vaporization of the palladium cube used for their cathode, the partial destruction of their lab bench, a small hole in the concrete floor and damage to the fume hood.[15]

Electrolysis cell schematic

In their original set-up, Fleischmann and Pons used a Dewar flask (a double-walled vacuum flask) for the electrolysis, so that heat conduction would be minimal on the side and the bottom of the cell (only 5 % of the heat loss in this experiment). The cell flask was then submerged in a bath maintained at constant temperature to eliminate the effect of external heat sources. They used an open cell, thus allowing the gaseous deuterium and oxygen resulting from the electrolysis reaction to leave the cell, along with some heat. It was necessary to replenish the cell with heavy water at regular intervals. The authors said that, since the cell was tall and narrow, the bubbling action of the gas kept the electrolyte well mixed and of a uniform temperature. Special attention was paid to the purity of the palladium cathode and electrolyte to prevent the build-up of material on its surface, especially after long periods of operation.

The cell was also instrumented with a thermistor to measure the temperature of the electrolyte, and an electrical heater to generate pulses of heat and calibrate the heat loss due to the gas outlet. After calibration, it was possible to compute the heat generated by the reaction.[1]

A constant current was applied to the cell continuously for many weeks, and heavy water was added as necessary. For most of the time, the power input to the cell was equal to the power that went out of the cell within measuring accuracy, and the cell temperature was stable at around 30 °C. But then, at some point (and in some of the experiments), the temperature rose suddenly to about 50 °C without changes in the input power, for durations of 2 days or more. The generated power was calculated to be about 20 times the input power during the power bursts. Eventually the power bursts in any one cell would no longer occur and the cell was turned off.

In 1988, Fleischmann and Pons applied to the United States Department of Energy for funding towards a larger series of experiments. Up to this point they had been funding their experiments using a small device built with $100,000 out-of-pocket.[16] The grant proposal was turned over for peer review, and one of the reviewers was Steven E. Jones of Brigham Young University.[16] Jones had worked on muon-catalyzed fusion for some time, and had written an article on the topic entitled "Cold nuclear fusion" that had been published in Scientific American in July 1987. Fleischmann and Pons and co-workers met with Jones and co-workers on occasion in Utah to share research and techniques. During this time, Fleischmann and Pons described their experiments as generating considerable "excess energy", in the sense that it could not be explained by chemical reactions alone.[17] They felt that such a discovery could bear significant commercial value and would be entitled to patent protection. Jones, however, was measuring neutron flux, which was not of commercial interest.[16] In order to avoid problems in the future, the teams appeared to agree to simultaneously publish their results, although their accounts of their March 6 meeting differ.[18]

In mid-March, both research teams were ready to publish their findings, and Fleischmann and Jones had agreed to meet at an airport on March 24 to send their papers to Nature via FedEx.[18] Fleischmann and Pons, however, broke their apparent agreement, submitting their paper to the Journal of Electroanalytical Chemistry on March 11, and disclosing their work via a press conference on March 23.[16] Jones, upset, faxed in his paper to Nature after the press conference.[18]

Reaction to the announcement[edit]

The press initially reported on the experiments widely, and due to the surmised beneficial commercial applications of the Utah experiments, "scores of laboratories in the United States and abroad" attempted to repeat the experiments.[19] The announcement raised hopes of a cheap and abundant source of energy.[2]

On April 10, 1989, Fleischmann and Pons, who later suggested pressure from patent attorneys, published a rushed "preliminary note" in the Journal of Electroanalytical Chemistry.[1] This paper notably contained a gamma peak without its corresponding Compton edge, a discrepancy that triggered accusations of fraud.[20][21] Their "preliminary note" was followed up a year later in July 1990, when a much longer paper, going into details of calorimetry but without any nuclear measurements, was published in the same journal.[17]

Also occurring on April 10, a team lead by John Bockris at Texas A&M University published their results of excess heat, followed up by a team at the Georgia Institute of Technology who observed production of neutrons.[22] Both results were widely reported on in the press. The Georgia Institute of Technology team later retracted their announcement.[23] For the next six weeks, additional competing claims, counterclaims and suggested explanations kept what was referred to as "cold fusion" or "fusion confusion" in the news.[24]

On April 12, Pons received a standing ovation from about 7,000 chemists at the semi-annual meeting of the American Chemical Society. The University of Utah asked Congress to provide $25 million to pursue the research,[25] and Pons was scheduled to meet with representatives of President Bush in early May.

Then on May 1, the American Physical Society held a session on cold fusion, which included several reports of experiments that failed to produce evidence of cold fusion. A second session began the next day with other negative reports, and eight of the nine leading speakers stated that they considered the initial Utah claim dead.[26] Dr. Steven E. Koonin of Caltech described the Utah report as a result of "the incompetence and delusion of Pons and Fleischmann."[26] Dr. Douglas R. O. Morrison, a physicist representing CERN, called the entire episode an example of pathological science.[3]

In June 1989, John Bockris and his team at Texas A&M published their previously informal report of tritium generation.[27] In September, they reported the sporadic observation of excess heat.[28] In August, the state of Utah, which runs the University of Utah, invested $4.5 million to create the National Cold Fusion Institute.[29] Nature published papers critical of cold fusion in July and November.[30][31]

1989 DOE panel[edit]

In November, a special panel formed by the Energy Research Advisory Board, under a charge of the United States Department of Energy, said that it was not possible to state categorically that cold fusion has been convincingly either proved or disproved.[32] The experimental results of excess heat from calorimetric cells reported to them did not present convincing evidence that useful sources of energy will result from the phenomena attributed to cold fusion. These experiments did not present convincing evidence to associate the reported anomalous heat with a nuclear process. Current understanding of hydrogen in solids gives no support for the occurrence of cold fusion in solids. Nuclear fusion at room temperature, of the type discussed in this report, would be contrary to all understanding gained of nuclear reactions in the last half century; it would require the invention of an entirely new nuclear process.

The panel "recommended against the establishment of special programs or research centers to develop cold fusion", but was "sympathetic toward modest support for carefully focused and cooperative experiments within the present funding system." The Panel recommended that "the cold fusion research efforts in the area of heat production focus primarily on confirming or disproving reports of excess heat" and stated that "investigations designed to check the reported observations of excess tritium in electrolytic cells are desirable.". [33]

Further developments (1989-2004)[edit]

After the 1989 review by the DOE, cold fusion was generally seen as an example of pathological science. Science writers Robert L. Park and Gary Taubes have published books criticizing cold fusion experiments and researchers.[34][35]

In June 1990, Gary Taubes wrote an editorial in Science suggesting that Texas A&M cells might have been spiked with tritiated water.[36] A 3-professor panel of Texas A&M later found that none of the experiments were fraudulently conducted, saying that spiking was unlikely because scientists got different results when they tested the spiking theory by intentionally putting tritium in water.[37][38] John Bockris later published his side of the controversy and a defense of academic freedom in "Accountability in Research".[39]

In 1991, researcher Andrew Riley was killed when a cold fusion cell exploded, possibly due to accumulation of deuterium gas and the failure of a safety valve.[40]

In September 1990, Dr. Fritz Will, Director of the National Cold Fusion Institute, compiled a list 92 groups of researchers from 10 different countries that had reported excess heat, tritium, helium4, neutrons or other nuclear effects.[41] Proponents estimate that 3,000 cold fusion papers have been published, [42] including over 1,000 journal papers and books, where the latter number includes both pro and con articles.[α]

Fleischmann and Pons relocated their laboratory to France under a grant from the Toyota Motor Corporation. The laboratory, IMRA, was closed in 1998 after spending £12 million on cold fusion work.[43]

A cold fusion calorimeter of the open type, used at the New Hydrogen Energy Institute in Japan. Source: SPAWAR/US Navy TR1862

Between 1992 and 1997, Japan's Ministry of International Trade and Industry sponsored a "New Hydrogen Energy Program" of US$20 million to research cold fusion. Announcing the end of the program, Dr. Hideo Ikegami stated in 1997 "We couldn't achieve what was first claimed in terms of cold fusion." He added, "We can't find any reason to propose more money for the coming year or for the future."[44]

In 1994, Dr. David Goodstein described cold fusion as "a pariah field, cast out by the scientific establishment. Between [cold fusion] and respectable science there is virtually no communication at all. Cold fusion papers are almost never published in refereed scientific journals, with the result that those works don't receive the normal critical scrutiny that science requires. On the other hand, because the Cold-Fusioners see themselves as a community under siege, there is little internal criticism. Experiments and theories tend to be accepted at face value, for fear of providing even more fuel for external critics, if anyone outside the group was bothering to listen. In these circumstances, crackpots flourish, making matters worse for those who believe that there is serious science going on here."[45]

Most people attempting to publish anything about the subject faced rejection of their papers. The late Nobel Laureate Julian Schwinger (1918 - 1994) was so outraged by the way the APS treated his papers that he resigned in protest. [46] Cold fusion researchers said that cold fusion was being suppressed, and that skeptics suffered from "pathological disbelief".[47] They said that there was virtually no possibility for funding in cold fusion in the United States, and no possibility of getting published.[48] They said that people in universities refused to work on it because they would be ridiculed by their colleagues.[49]

Researchers share their results at the International Conference on Cold Fusion, recently renamed the International Conference on Condensed Matter Nuclear Science. The conference is held every 12 to 18 months in various countries around the world, and is hosted by The International Society for Condensed Matter Nuclear Science, a scientific organization that was founded as a professional society to support research efforts and to communicate experimental results. A few periodicals emerged in the 1990s that covered developments in cold fusion and related new energy sciences (Fusion Facts, Cold Fusion Magazine, Infinite Energy Magazine, and New Energy Times).

In February 2002, the U.S. Navy revealed that its researchers had been studying cold fusion on the quiet more or less continuously since 1989. Researchers at their Space and Naval Warfare Systems Center in San Diego released a two-volume report, entitled "Thermal and nuclear aspects of the Pd/D2O system," with a plea for proper funding.[50]

2004 DOE panel[edit]

In 2004, the DOE organized another panel to take a look at cold fusion developments since 1989 to determine if their policies towards cold fusion should be altered.[51]

It concluded: "While significant progress has been made in the sophistication of calorimeters since the review of this subject in 1989, the conclusions reached by the reviewers today are similar to those found in the 1989 review." "The nearly unanimous opinion of the reviewers in the 2004 review was that funding agencies should entertain individual, well-designed proposals for experiments that address specific scientific issues relevant to the question of whether or not there is anomalous energy production in Pd/D systems, or whether or not D-D fusion reactions occur at energies on the order of a few electron volts (eV). These proposals should meet accepted scientific standards and undergo the rigors of peer review. No reviewer recommended a focused federally funded program for low energy nuclear reactions." "The reviewers believed that this field would benefit from the peer-review processes associated with proposal submission to agencies and paper submission to archival journals."[52]

Recent developments[edit]

The reports of excess heat and anomalous tritium production[α] have been met by most scientists with skepticism,[53] although discussion in professional settings still continues. The American Chemical Society's (ACS) 2007 conference in Chicago held an "invited symposium" on cold fusion and low-energy nuclear reactions, and thirteen papers were presented at the "Cold Fusion" session of the 2006 American Physical Society (APS) March Meeting in Baltimore.[54][55] Articles supporting cold fusion have been published in peer reviewed journals such as Naturwissenschaften, Japanese Journal of Applied Physics, European Physical Journal A, European Physical Journal C, International Journal of Hydrogen Energy, Journal of Solid State Phenomena, Journal of Electroanalytical Chemistry, and Journal of Fusion Energy. [56][57]

In 2007, a United States Naval Research Laboratory researcher with no previous experience with cold fusion wrote a review of experiments with solid palladium cathodes and electrolytes with deuterium, or with D2 gas loaded in palladium powders. The author said that more than 10 groups worldwide have reported the measurement of excess heat in 1/3 of their experiments and that most of the research groups have reported occasionally seeing 50-200% excess heat for hours to days. The difficulty of reproducing the research results were explained by the author as due to different research teams being able to achieve very different deuterium loading ratios within palladium.[58]

In 2008, the government of India reviewed the field.[59] Dr. M. R. Srinivasan, former chairman of the Atomic Energy Commission of India said: "There is some science here that needs to be understood. We should set some people to investigate these experiments. There is much to be commended for the progress in the work. The neglect should come to an end".[60] On May 22, 2008, Arata and Zhang publicly demonstrated what they say is a cold fusion reactor at Osaka University.[61][62]

Summary of evidence for cold fusion[edit]

Cold fusion experiments have been conducted with many types of apparatus. The main constituents are:

Cold fusion has remained controversial, but several experimenters have reported excess heat, X-rays, gamma rays, neutrons, protons, helium-4, helium-3 , and/or anomalous isotopic distributions.[64] No experiment has unequivocally produced a particle emission spectrum matching that predicted by observations in nuclear science and high-energy physics. There is still no satisfactory theory explaining condensed matter nuclear science but many explanations have been proposed, several of which do not require new physics. [65]

Excess heat[edit]

The excess power observed in some experiments is reported to be beyond that attributable to ordinary chemical or solid state sources; proponents attribute this excess power to nuclear fusion reactions.[51][58]

In addition to Fleischmann and Pons, the generation of excess heat has been reported by others, including:

In 1993, Fleischmann reported "heat-after-death" experiments: he observed the continuing generation of excess heat after the electric current supplied to the electrolytic cell was turned off.[73] Such observations have been reported by others.[74][75]

The cold fusion researchers who presented their review document to the 2004 DOE panel said that "the hypothesis that the excess heat effect arises only as a consequence of errors in calorimetry was considered, studied, tested, and ultimately rejected".[76]

Nuclear products[edit]

A CR-39 detector showing possible nuclear activity in cold fusion experiments at SSC San Diego.[77]

The cold fusion researchers who presented their review document to the 2004 DOE panel on cold fusion said that there are insufficient chemical reaction products to account for the excess heat by several orders of magnitude.[78] They reported a rate of helium production measured in the gas stream which varied linearly with excess power. They reported that 4He was produced at levels above that of the concentration in air.[79] However, the amount of helium in the gas stream was about half of what would be expected for a heat source of the type D + D → 4He.

Cold fusion advocates have reported detection in their experiments of many kinds of radiation: alpha, beta, gamma, proton, triton. However, neutrons and other energetic emissions were never found in quantities commensurate with the excess heat, as would be expected by conventional fusion theory. This leads to the conjecture that the new process is somehow converting nuclear energy directly to heat.[80]

In 2007, the Space and Naval Warfare Systems Center San Diego reported their observation of pits in CR-39 detectors during D/Pd codeposition experiments in the European Physical Journal. They said that those pits have features consistent with those observed for nuclear-generated tracks, that the Pd cathode is the source of those pits, and that they are not due to contamination or chemical reactions. They attributed some pits to knock-ons due to neutrons, and said that other pits are consistent with those obtained for alpha particles.[81] Further analysis of "triple pits" suggests that Deuterium-Tritium reactions occurring inside the Pd lattice produce neutrons with an energy above 9.6 MeV.[82]

Nuclear transmutations[edit]

In nuclear reactions, a chemical element may be transmuted into another. There are reports by cold fusion advocates of nuclear transmutations and isotope anomalies in cold fusion experiments.[83]

Iwamura and associates published what they say is evidence of transmutations in the Japanese Journal of Applied Physics in 2002.[84] Instead of using electrolysis, they forced deuterium gas to permeate through a thin layer of caesium or strontium deposited on calcium oxide and palladium, while periodically analyzing the nature of the surface through X-ray photoelectron spectroscopy. They said that as the deuterium gas permeated over a period of a week, cesium appeared to be progressively transmuted into praseodymium while strontium appeared to be transmuted into molybdenum with anomalous isotopic composition representing an addition of four deuterium nuclei to the original nuclide. When the deuterium gas was replaced by hydrogen in control experiments, no transmutation was reported to be observed. The authors said that they analyzed, and then rejected, the possibility of explaining these various observations by contaminations or migration of impurities from the palladium interior.[85]

In 2001, Di Giulio reported transmutations in a similar gas-loading experiment with Palladium. [86]

Criticism[edit]

In the original 1989 DOE review,[87] skepticism towards cold fusion focused on four issues: the precision of calorimetry, the lack of consistently reproducible results, the absence of nuclear products in quantities consistent with the excess heat, and the lack of a mainstream theoretical mechanism. In the subsequent years considerable efforts have been made on these fronts, but today some issues still remain and some new ones have arisen.

Precision and accuracy of calorimetry[edit]

Main article: Calorimetry in cold fusion experiments

(userfied in User:Abd/Calorimetry in cold fusion experiments)

In the first years after the Fleishmann-Pons announcement various challenges were put forth. The efficacy of the stirring method in the Fleischmann-Pons experiment, and thus the validity of the temperature measurements was disputed by Browne.[88] The experiment has also been criticized by Wilson.[89] The possibility that electrochemically mediated deuterium-oxygen recombination can cause the appearance of excess heat was discussed by Shkedi[90] and Jones.[91]

The 2004 DOE panel noted that significant progress has been made in the sophistication of calorimeters since 1989. Evaluations by the reviewers ranged from: 1) evidence for excess power is compelling, to 2) there is no convincing evidence that excess power is produced when integrated over the life of an experiment. The reviewers were split approximately evenly on this topic. [51]

Many of the reviewers noted that poor experiment design, documentation, background control and other similar issues hampered the understanding and interpretation of the results presented to the DOE panel. The reviewers who did not find the production of excess power convincing said that excess power in the short term is not the same as net energy production over the entire time of an experiment, that such short-term excess power is only a few percent of the total external power applied and hence calibration and systematic effects could account for the purported effect, that all possible chemical and solid state causes of excess heat had not been investigated and eliminated as an explanation, that the magnitude of the effect had not increased after over a decade of work.

Kirk Shanahan suggested that a calibration constant shift could explain apparent excess heat signals, and that such a shift could occur by a redistribution of heat in a F&P cell. He further speculated that such a redistribution would occur if recombination at the electrode became active, but acknowledged that this is not experimentally proven.[92][93] Cold fusion proponents say that such speculations are not supported by experimental results (in particular, that the measured volume of recombined output evolved gases does not allow for recombination within the cell), a statement that Shanahan later disputed.[75][94]

Lack of reproducibility of excess heat[edit]

In 1989, the DOE panel noted that "Even a single short but valid cold fusion period would be revolutionary. As a result, it is difficult convincingly to resolve all cold fusion claims since, for example, any good experiment that fails to find cold fusion can be discounted as merely not working for unknown reasons." [32].

The cold fusion researchers who presented their review document to the 2004 DOE panel on cold fusion said that the observation of excess heat has been reproduced, that it can be reproduced at will under the proper conditions, and that many of the reasons for failure to reproduce it have been discovered.[95] Contrary to these assertions, most reviewers stated that the effects are not repeatable, the magnitude of the effect has not increased in over a decade of work, and that many of the reported experiments were not well documented. [96]

Missing nuclear products[edit]

The fusion of two deuterium nuclei usually produces either a tritium nucleus and a proton, or a helium-3 (3He) nucleus and a neutron. The level of neutrons, tritium and 3He actually observed in the Fleischmann-Pons experiments have been well below the level expected in view of the heat generated, implying that these fusion reactions cannot explain it. If the excess heat were generated by the fusion of two deuterium nuclei into helium (4He), a reaction which is normally extremely rare, gamma rays and helium (alpha particles) would be expected. In 1989, insufficient levels of helium (alpha particles) and gamma rays were observed to explain the excess heat.[97]

New information was presented in 2004 to the DOE review panel regarding the production of 4He.[98] When members of the panel were asked about the evidence of low energy nuclear reactions, twelve of the eighteen did not feel that there was any conclusive evidence, five found the evidence "somewhat convincing", and one was entirely convinced. The evidence of D+D fusion was taken as convincing or somewhat convincing by some reviewers; for others the lack of consistency was an indication that the overall hypothesis was not justified. Contamination of apparatus or samples by air containing 4He was cited as one possible cause for false positive results in some measurements.[96]

An example of this was published by Clarke et al. in 2003.[99] Their paper reported on the analysis of gases found in four ‘Case-type’ cells obtained from the McKubre group at SRI International, a primary cold fusion research group. The Abstract states: “One sample appears to be identical in composition to air, and the other three have been seriously affected by leak(s) into and from the SRI cells.” The Conclusions states: "The samples of gas from Case-type cells provided to us by the SRI workers do not show any evidence of production of 4He via cold fusion. Our analytical results can be explained by a combination of two factors: (a) severe leak(s) that allowed air into the cells, and also caused removal of gases including hydrogen from the cells to the atmosphere, and (b) the action of the Pd/C catalyst on O2 in the incoming air, which resulted in high CO and CO2 concentrations—telltale fingerprints of chemical combination of atmospheric O2 and C in the catalyst."

Insufficient theoretical explanations [edit]

Temperatures and pressures similar to those in stars are required for conventional nuclear fusion. The 1989 DOE panel said that such "nuclear fusion at room temperature [...] would be contrary to all understanding gained of nuclear reactions in the last half century" and "it would require the invention of an entirely new nuclear process." [33] but it also recognized that "the failure of a theory to account for cold fusion can be discounted on the grounds that the correct explanation and theory has not been provided",[32] that is, the lack of a satisfactory explanation could not be used to dismiss experimental evidence.

Cold fusion observations are contrary to the conventional physics of nuclear fusion in several ways :

  • The average density of deuterium atoms in the palladium rod seems vastly insufficient to force pairs of nuclei close enough for fusion to occur according to mechanisms known to mainstream theories. The average distance is approximately 0.17 nanometers, a distance at which the attractive strong nuclear force cannot overcome the Coulomb repulsion. Deuterium atoms are closer together in D2 gas molecules, which do not exhibit fusion.[100]
  • There is no known mechanism that would release fusion energy as heat instead of radiation within the relatively small metal lattice.[101] The direct conversion of fusion energy into heat is not possible because of energy and momentum conservation and the laws of special relativity.[102]
  • Transmutations introduce additional discrepancies between observations and conventional theory because of the increased Coulomb barrier.

Cold fusion researchers acknowledge these issues and have proposed various speculative theories (for a full review, see Storms 2007) to explain the reported observations, but none has received mainstream acceptance.[103]

Refrences[edit]

  1. ^ a b c Fleischmann & Pons 1989, p. 301.
  2. ^ a b Browne 1989, para. 1.
  3. ^ a b Browne 1989, para. 29.
  4. ^ US DOE 2004
  5. ^ e.g. Mosier-Boss et al. 2008
  6. ^ Van Noorden 2007, para. 2.
  7. ^ Chubb et al. 2006.
  8. ^ a b c d US DOE 1989, p. 7.
  9. ^ Kowalski 2004, II.A2.
  10. ^ Fleischmann 2003, p. 1.
  11. ^ Fleischmann 2002.
  12. ^ a b Fleischmann 2003, p. 3.
  13. ^ Leggett 1989.
  14. ^ Lewenstein 1994 p. 21.
  15. ^ Krivit 2008, p. 9, Browne 1989.
  16. ^ a b c d Crease & Samios 1989, p. V1.
  17. ^ a b Fleischmann et al. 1990, p. 293.
  18. ^ a b c Lewenstein 1994, p. 8.
  19. ^ Browne 1989, para. 13.
  20. ^ Tate 1989, p. 1.
  21. ^ Platt 1989.
  22. ^ Broad 1989.
  23. ^ Wilford 1989.
  24. ^ Bowen 1989.
  25. ^ Browne 1989, para. 8.
  26. ^ a b Browne 1989.
  27. ^ Packham 1989.
  28. ^ Kainthla 1989
  29. ^ Joyce 1990.
  30. ^ Gai et al. 1989, pp. 29–34.
  31. ^ Williams et al. 1989, pp. 375–384.
  32. ^ a b c US DOE 1989, p. 36.
  33. ^ a b US DOE 1989, p. 37.
  34. ^ Taubes 1993.
  35. ^ Park 2000.
  36. ^ Taubes 1990.
  37. ^ New York Times 1990.
  38. ^ Storms 1990.
  39. ^ Bockris 2000.
  40. ^ Charles 1992.
  41. ^ Mallove 1991, p. 246-248.
  42. ^ Anderson 2007.
  43. ^ Voss 1999.
  44. ^ Pollack 1997, p. C4.
  45. ^ Goodstein 1994.
  46. ^ Storms 2007
  47. ^ Josephson 2004.
  48. ^ Feder 2004, p. 27.
  49. ^ Rusbringer 2005.
  50. ^ Mullins 2004
  51. ^ a b c US DOE 2004, p. 3.
  52. ^ US DOE 2004, p. 5.
  53. ^ Feder 2005.
  54. ^ Van Noorden 2007, para. 2.
  55. ^ Chubb et al. 2006.
  56. ^ cited by Krivit, Steven, "Selected Papers - Low Energy Nuclear Reactions," [1]
  57. ^ Di Giulio 2002.
  58. ^ a b Hubler 2007.
  59. ^ Jayaraman 2008.
  60. ^ Srinivasan 2008.
  61. ^ Cartwright 2008.
  62. ^ Cartwright 2008b.
  63. ^ Storms 2007, p. 144-150.
  64. ^ Biberian 2007.
  65. ^ Biberian 2007.
  66. ^ Oriani et al. 1990, pp. 652–662, cited by Storms 2007, p. 61.
  67. ^ Bush et al. 1991, cited by Biberian 2007.
  68. ^ e.g. Storms 1993, Hagelstein et al. 2004.
  69. ^ Miles et al. 1993, cited by Biberian 2007.
  70. ^ e.g. McKubre 1994, Hagelstein et al. 2004.
  71. ^ e.g. Arata & Zhang 1998, Hagelstein et al. 2004.
  72. ^ Gozzi 1998, cited by Biberian 2007.
  73. ^ Fleischmann 1993.
  74. ^ Mengoli 1998.
  75. ^ a b Szpak 2004.
  76. ^ Hagelstein et al. 2004, p. 1.
  77. ^ Mosier-Boss, Szpak & Gordon 2007, slide 7
    reported in Krivit 2007, p. 2.
  78. ^ Hagelstein et al. 2004, p. 7.
  79. ^ Hagelstein et al. 2004, p. 10.
  80. ^ Hagelstein et al. 2004, p. 7.
  81. ^ Mosier-Boss et al. 2007.
  82. ^ Mosier-Boss et al. 2008
  83. ^ Storms 2007, p. 93-95.
  84. ^ Iwamura, Sakano & Itoh 2002, pp. 4642–4650.
  85. ^ Iwamura, Sakano & Itoh 2002, p. 4648-4649.
  86. ^ Di Giulio 2002.
  87. ^ US DOE 1989, pp. 6–8.
  88. ^ Browne 1989, para. 16.
  89. ^ Wilson 1992.
  90. ^ Shkedi et al. 1995.
  91. ^ Jones et al. 1995, p. 1.
  92. ^ Shanahan 2002.
  93. ^ Shanahan 2006
  94. ^ Storms 2007, p. 41.
  95. ^ Hagelstein et al. 2004, p. 14.
  96. ^ a b US DOE 2004, p. 3.
  97. ^ US DOE 1989, pp. 5–6.
  98. ^ Hagelstein et al. 2004.
  99. ^ Clarke 2003.
  100. ^ US DOE 1989, pp. 6–7.
  101. ^ Goodstein 1994, p. 528.
  102. ^ Kee 1999, p. 5.
  103. ^ Biberian 2007.
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