I want to thank Curt Youngs for sending me this to read.
On an Experimentus Crusis for Optics
This is a excellent paper. Transverse vs Longitudinal waves, the Malus effect, dis-harmonic vibrations are absorbed by the medium.
This paper was accepted for publish at the General Science Journal
This is a model that explain the interactions of the universe without gravity. This is not a decay model, It is an interactive information model. Inorder to realize a need for a new model requires disproving certain understandings that permiate cosmology. A field (E) cannot equal a scalar (mass) * a vector (C) ^2. It also describes baryonic expression of information. Comments are welcome, Anonymous comments with non-relevant links will not be posted.
Saturday, November 20, 2010
Thursday, November 18, 2010
How is matter created?
In this model I describe how baryonic matter is created from dark matter. I feel this is a topic that I have not fully described to the extent the model requires.
Definitions in this model: (described in published papers)
Dark Matter: non-rotating gluons compressing together.
Baryonic Matter: Three rotating gluons spin to form a baryon.
Model Requirements:
The requirements for baryogenesis is that baryons are easily created by interactions within dark matter, and/or between baryons and dark matter.
General Baryogenesis:
As baryonic matter plows through the dark matter medium, the magnetic field of the baryon causes motion/rotation in the non-rotating gluons. The dark matter gluons start rotating and coalescing into Baryons.
The greater the baryonic density, the more interactions that create baryons from dark matter. This rate is variable. The W+/- Boson (magnetism) -- Dark Matter interaction is the most common but Z Bosons and Gluons can interact with DM. DM does not create an electron so it cannot interact with the photon.
We see the result of this process in pictures like this from the Fermi space telescope. I originally found this at Q SPACE
Credit: NASA
This is the baryon's commutative/composite shape as described in this model. This is the shape of helium. This shape shows properties of helium.
Where as elliptical galaxies are more like hydrogen.
Definitions in this model: (described in published papers)
Dark Matter: non-rotating gluons compressing together.
Baryonic Matter: Three rotating gluons spin to form a baryon.
Model Requirements:
The requirements for baryogenesis is that baryons are easily created by interactions within dark matter, and/or between baryons and dark matter.
General Baryogenesis:
As baryonic matter plows through the dark matter medium, the magnetic field of the baryon causes motion/rotation in the non-rotating gluons. The dark matter gluons start rotating and coalescing into Baryons.
The greater the baryonic density, the more interactions that create baryons from dark matter. This rate is variable. The W+/- Boson (magnetism) -- Dark Matter interaction is the most common but Z Bosons and Gluons can interact with DM. DM does not create an electron so it cannot interact with the photon.
We see the result of this process in pictures like this from the Fermi space telescope. I originally found this at Q SPACE
Credit: NASA
This is the baryon's commutative/composite shape as described in this model. This is the shape of helium. This shape shows properties of helium.
- A noble gas.
- Its electrons are away from the nucleus along a plane.
- This plane is perpendicular to the magnetic field.
- This is a stable spiral galaxy. It is not effected by (severely) another galaxy's magnetic field.
- They do not interact well with other atoms/galaxies.
- Closed loop
- High intensity core rotating.
Where as elliptical galaxies are more like hydrogen.
- Can be highly charged