Cosmological Redshift and Light Velocity in Vacuum: Difference between revisions
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An alternative to the explanation of the redshift by Doppler effect is proposed. Since it has been shown in particle generation by electrtomagnetic interaction and in other examples that a vacuum is not a void, but has a material character, it is reasonable to assume that light waves meet a certain resistance when propagating through vacuum. When a corresponding term is introduced in the wave equation, the solution results in a change of velocity and wavelength, but not in frequency. At the same time there is extinction over very long distances, and this provides a natural explanation of Albers' paradox.[[Category:Scientific Paper]] | An alternative to the explanation of the redshift by Doppler effect is proposed. Since it has been shown in particle generation by electrtomagnetic interaction and in other examples that a vacuum is not a void, but has a material character, it is reasonable to assume that light waves meet a certain resistance when propagating through vacuum. When a corresponding term is introduced in the wave equation, the solution results in a change of velocity and wavelength, but not in frequency. At the same time there is extinction over very long distances, and this provides a natural explanation of Albers' paradox. | ||
[[Category:Scientific Paper|cosmological redshift light velocity vacuum]] | |||
Latest revision as of 12:12, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | Cosmological Redshift and Light Velocity in Vacuum |
| Author(s) | Eugene I Shtyrkov |
| Keywords | Doppler effect, cosmological redshift, light velocity, vacuum |
| Published | 1992 |
| Journal | Galilean Electrodynamics |
| Volume | 3 |
| Number | 4 |
| Pages | 66-68 |
Abstract
An alternative to the explanation of the redshift by Doppler effect is proposed. Since it has been shown in particle generation by electrtomagnetic interaction and in other examples that a vacuum is not a void, but has a material character, it is reasonable to assume that light waves meet a certain resistance when propagating through vacuum. When a corresponding term is introduced in the wave equation, the solution results in a change of velocity and wavelength, but not in frequency. At the same time there is extinction over very long distances, and this provides a natural explanation of Albers' paradox.