Testing a Mechanical Behavior of Light: Difference between revisions
Imported from text file |
Imported from text file |
||
| (One intermediate revision by the same user not shown) | |||
| Line 16: | Line 16: | ||
==Abstract== | ==Abstract== | ||
We model photons as being rigid bodies. Based only on Newtonian mechanics, we reproduce numerically the Fresnel Diffraction Experiment. In this way, a large number of rigid bodies are thrown against a single slit. The rigid bodies used are spherical and their center of mass and centroid are not coincident. Thus, each rigid body describes a cycloid (presenting amplitude, frequency and phase - as well as the DeBroglie wave). The numerical results indicate a wave pattern relatively similar to those achieved by experimental results. Different apertures and depths of the slit were tested. | We model photons as being rigid bodies. Based only on Newtonian mechanics, we reproduce numerically the Fresnel Diffraction Experiment. In this way, a large number of rigid bodies are thrown against a single slit. The rigid bodies used are spherical and their center of mass and centroid are not coincident. Thus, each rigid body describes a cycloid (presenting amplitude, frequency and phase - as well as the DeBroglie wave). The numerical results indicate a wave pattern relatively similar to those achieved by experimental results. Different apertures and depths of the slit were tested. | ||
[[Category:Relativity]] | [[Category:Scientific Paper|testing mechanical behavior light]] | ||
[[Category:Relativity|testing mechanical behavior light]] | |||
Latest revision as of 21:58, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | Testing a Mechanical Behavior of Light |
| Read in full | Link to paper |
| Author(s) | Luiz Eduardo Azambuja Sauerbronn |
| Keywords | Rigid Bodies, Collisions, Diffraction, Fresnel, Light, Laser |
| Published | 2012 |
| Journal | Proceedings of the NPA |
| Volume | 9 |
| No. of pages | 7 |
| Pages | 503-509 |
Read the full paper here
Abstract
We model photons as being rigid bodies. Based only on Newtonian mechanics, we reproduce numerically the Fresnel Diffraction Experiment. In this way, a large number of rigid bodies are thrown against a single slit. The rigid bodies used are spherical and their center of mass and centroid are not coincident. Thus, each rigid body describes a cycloid (presenting amplitude, frequency and phase - as well as the DeBroglie wave). The numerical results indicate a wave pattern relatively similar to those achieved by experimental results. Different apertures and depths of the slit were tested.