Difference between revisions of "Implications of Infinite Current Densities at Idealized DC Generator Poles"
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− | The discovery of the necessity of infinite current densities at idealized DC generator poles needs search for applications, among others cold fusion. A mathematical proof has been made elsewhere predicting the appearance of infinite current densities in the vicinity of idealized DC generator poles with a vanishing linear extension. The discovery was made, as a complete DC circuit was being analyzed mathematically as a part of the analysis of experimental results with Ampere's bridge in the 1980s. The author has proposed that the research upon among others cold fusion would benefit from the discovery, as very high energy densities will be needed in order to achieve fusion, and this will happen in an electric circuit, too, provided the current density is high enough. Since no reactions have been observed thus far with respect to the publication of the discovery, it seems necessary to emphasize this discovery again through a special paper, focusing solely upon the analysis of a DC source. More generally, the discovery will be of great use within all calculations of electromagnetic forces involving a DC generator, or a discharging capacitor, as well.[[Category:Scientific Paper]] | + | The discovery of the necessity of infinite current densities at idealized DC generator poles needs search for applications, among others cold fusion. A mathematical proof has been made elsewhere predicting the appearance of infinite current densities in the vicinity of idealized DC generator poles with a vanishing linear extension. The discovery was made, as a complete DC circuit was being analyzed mathematically as a part of the analysis of experimental results with Ampere's bridge in the 1980s. The author has proposed that the research upon among others cold fusion would benefit from the discovery, as very high energy densities will be needed in order to achieve fusion, and this will happen in an electric circuit, too, provided the current density is high enough. Since no reactions have been observed thus far with respect to the publication of the discovery, it seems necessary to emphasize this discovery again through a special paper, focusing solely upon the analysis of a DC source. More generally, the discovery will be of great use within all calculations of electromagnetic forces involving a DC generator, or a discharging capacitor, as well. |
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+ | [[Category:Scientific Paper|implications infinite current densities idealized dc generator poles]] |
Latest revision as of 10:32, 1 January 2017
Scientific Paper | |
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Title | Implications of Infinite Current Densities at Idealized DC Generator Poles |
Read in full | Link to paper |
Author(s) | Jan Olof Jonson |
Keywords | {{{keywords}}} |
Published | 2008 |
Journal | Proceedings of the NPA |
Volume | 5 |
Number | 1 |
No. of pages | 4 |
Pages | 119-120 |
Read the full paper here
Abstract
The discovery of the necessity of infinite current densities at idealized DC generator poles needs search for applications, among others cold fusion. A mathematical proof has been made elsewhere predicting the appearance of infinite current densities in the vicinity of idealized DC generator poles with a vanishing linear extension. The discovery was made, as a complete DC circuit was being analyzed mathematically as a part of the analysis of experimental results with Ampere's bridge in the 1980s. The author has proposed that the research upon among others cold fusion would benefit from the discovery, as very high energy densities will be needed in order to achieve fusion, and this will happen in an electric circuit, too, provided the current density is high enough. Since no reactions have been observed thus far with respect to the publication of the discovery, it seems necessary to emphasize this discovery again through a special paper, focusing solely upon the analysis of a DC source. More generally, the discovery will be of great use within all calculations of electromagnetic forces involving a DC generator, or a discharging capacitor, as well.