Magnetic Control of Discharge Tube Current: Difference between revisions
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This paper summarizes experiments that use magnetic fields to control the current in discharge tubes. In theory, the trajectory of electrons, in a magnetic field applied parallel to their initial direction of motion, describes a spiral path as these electrons follow the magnetic field lines. This results in an overall longer path with a higher probability of ionizing more gas molecules with a resulting increase in current (Yarwood 1945). In these experiments, the magnetic field was oriented parallel to the stream of electrons emitted from a cold cathode in a discharge tube. The experiments determined the magnetic field strength necessary to control tube current by lengthening the electron path.[[Category:Scientific Paper]] | This paper summarizes experiments that use magnetic fields to control the current in discharge tubes. In theory, the trajectory of electrons, in a magnetic field applied parallel to their initial direction of motion, describes a spiral path as these electrons follow the magnetic field lines. This results in an overall longer path with a higher probability of ionizing more gas molecules with a resulting increase in current (Yarwood 1945). In these experiments, the magnetic field was oriented parallel to the stream of electrons emitted from a cold cathode in a discharge tube. The experiments determined the magnetic field strength necessary to control tube current by lengthening the electron path. | ||
[[Category:Scientific Paper|magnetic control discharge tube current]] | |||
Latest revision as of 12:39, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | Magnetic Control of Discharge Tube Current |
| Author(s) | Timothy E Raney |
| Keywords | discharge tubes, electron path, experiment, magnetic fields |
| Published | 1999 |
| Journal | Electric Spacecraft Journal |
| Number | 29 |
| Pages | 10-11 |
Abstract
This paper summarizes experiments that use magnetic fields to control the current in discharge tubes. In theory, the trajectory of electrons, in a magnetic field applied parallel to their initial direction of motion, describes a spiral path as these electrons follow the magnetic field lines. This results in an overall longer path with a higher probability of ionizing more gas molecules with a resulting increase in current (Yarwood 1945). In these experiments, the magnetic field was oriented parallel to the stream of electrons emitted from a cold cathode in a discharge tube. The experiments determined the magnetic field strength necessary to control tube current by lengthening the electron path.