Two Types of Aether
James Maxwell modeled light as waves, and required for this an aether to propagate the waves. However, ever since the discovery of the photon, there has not been any need
The Aether as a Standing Wave
An aether of zero-point particles will have the overall behavior of a very high frequency standing wave. This is because the photons and neutrinos that make up the aether will constantly bump into each other. Since these particles have similar…
Pilot Waves vs. Wavelengths
The standard explanation for how Faraday cages work is that the metal mesh from which it is constructed will let through only those photons with sufficiently small wavelengths to fit through the openings. Wavelengths If a photon has a long…
The Casimir Effect
The Casimir effect is a weak force that acts between two neutral surfaces in close proximity to each other. It's usually attractive, but can also be repelling. Predicted by Hendrik Casimir The existence of this force was predicted in 1948…
Newton’s Cradle – Energy and Inertia
The strict particle model presented here makes no distinction between the subatomic level and macrolevel when it comes to motion. However, it does make two bold claims. One is that inertia is time delay in energy transfers. The other one…
Three Energy Levels at the Subatomic
When we go down to the subatomic level, we find that there are three distinct energy levels. They are, the zero-point level, the radiation level and the level of inertial matter. This is evident from the following observations. Zero-point vs…
The Twist of the Birkeland Current
Everywhere we look in the world around us, we find spiraling patterns. The shell of the Nautilus is often used as a symbol for this. The double helix of the DNA that make up the genetic code of life is…
Lightning and Gamma Rays
Terrestrial lightning is frequently accompanied by gamma rays. First as a flash, and then as a lingering afterglow that can last up to a minute. This can be explained in terms of an aether of low energy photons and neutrinos…
Floating Superconductors
When a superconductor is put close to a strong magnet, it will lock into the position where it has been put. It will neither fall nor rise. It will not slide off to the side.
Pilot Waves and Refraction
Pilot wave theory can be used to explain the double slit experiment, and how mirrors can reflect photons as perfectly as they do. Scatter Pilot waves help smooth out minor irregularities by providing a cushion to tiny particles like photons. Was…