Superconductivity and Electron Viscosity: Difference between revisions
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By applying quantum theory to fluid mechanics, it is shown why superconductivity was considered a low temperature phenomenon, but that under certain circumstances electron pairing and high currents in filaments will occur. In particular, it is found that bismuth at room temperatures cannot be far from superconductivity. | By applying quantum theory to fluid mechanics, it is shown why superconductivity was considered a low temperature phenomenon, but that under certain circumstances electron pairing and high currents in filaments will occur. In particular, it is found that bismuth at room temperatures cannot be far from superconductivity. | ||
[[Category:New Energy]] | [[Category:Scientific Paper|superconductivity electron viscosity]] | ||
[[Category:New Energy|superconductivity electron viscosity]] | |||
Latest revision as of 21:57, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | Superconductivity and Electron Viscosity |
| Author(s) | Robert L Carroll |
| Keywords | superconductivity, electron viscosity, quantum theory, fluid mechanics |
| Published | 1991 |
| Journal | Galilean Electrodynamics |
| Volume | 2 |
| Number | 1 |
| Pages | 10-12 |
Abstract
By applying quantum theory to fluid mechanics, it is shown why superconductivity was considered a low temperature phenomenon, but that under certain circumstances electron pairing and high currents in filaments will occur. In particular, it is found that bismuth at room temperatures cannot be far from superconductivity.