Crawler states "A simple experiment is presented which indicates that electromagnetic fields
propagate superluminally in the near-field next to an oscillating electric dipole source."
Very interesting. The key word in this is "NEAR-FIELD." If the distance between the emitter and the detector are less than a wavelength apart, the sub-photon MAGNETIC field is intact from the emitter to the detector. Once the current in the emitter changes direction, the magnetic field is ejected from the conductor and propagates with the electromagnetic wave at the speed of light. I did not realize anyone did a study of this so I do appreciate it. It does help support my model. If we can design a setup that propagates from NEAR-FIELD to NEAR-FIELD at long distances, we may be able to achieve faster-than-light communications. My proposal for faster-than-light communication showed a couple of alternatives how this could be achieved.
Introduction to Sub-photons
-
- Posts: 857
- Joined: Sun Oct 28, 2018 5:33 pm
Re: Introduction to Sub-photons
I am a bit rusty re Gasser & Dinu & Hertz & Co.
But, i think there are no (natural) waves. What we have is manmade pulses. So, describing the near-field in terms of wavelengths will probly lead to tears.
But, i think there are no (natural) waves. What we have is manmade pulses. So, describing the near-field in terms of wavelengths will probly lead to tears.
STR is krapp -- & GTR is mostly krapp.
The present Einsteinian Dark Age of science will soon end – for the times they are a-changin'.
The aether will return – it never left.
The present Einsteinian Dark Age of science will soon end – for the times they are a-changin'.
The aether will return – it never left.
-
- Posts: 114
- Joined: Sat Nov 18, 2023 2:22 pm
Re: Introduction to Sub-photons
This is very interesting Crawler.
The study states "The outgoing transverse waves reduce to the speed of light after they propagate about
one wavelength away from the source. "
I never realized this study was done. This is exactly what my model predicts.
Pretty cool.
The study states "The outgoing transverse waves reduce to the speed of light after they propagate about
one wavelength away from the source. "
I never realized this study was done. This is exactly what my model predicts.
Pretty cool.
Who is online
Users browsing this forum: No registered users and 1 guest