Thursday, July 3, 2008

Symmetric form: Logic problem

Symmetry is not natural in the universe. There are always differences.

For example a star has a great solar flare at T(n). A tremendous amount of energy has been released at one point on the star. Symmetry demands that a solar flare of equal strength and opposite direction is required at T(n). This is not natural.

Symmetry is a construct used to simplify multi-variable systems. Einstein and others only had their intuition to create these great thories, symmerty made these intuitions almost explainable. We barely know now how orbits function and they are not exactly as Newton, Einstein and others suggest. But, if it was not for their work we would still be living in caves. Symmetry is necessary to make the intuitive jump from 'the particles want to be together', to 'there is an observable process in particle dynamics'.

Symmetry has no physical evidence.

These are systems where certain variables do not induce a massive change to the overall system, yet do affect small variances to the system.

We know the earth does not have a symmetrical curvature of space/time. It is squashed and some areas have more pertubations than others. These variations occur when the density directly under the spacecraft changes. Traveling over an ocean has one curvature of space/time, whereas a massive mountain range has more density, thus a different curvature of space/time. These variations need to be incorperated in orbit design, else you lose the satellite.

Asymmetry occurs from the inablity to predict electron position. Nature is asymmertical.

The removal of symmetry allows discussuion on the effect of the shape of the earth at rest and at motion on the curvature of space/time.

Wednesday, July 2, 2008

Curvature of Space/Time

The curvature of space is a function of the density of baryons, the magnetic field, and radioactive particles emitted from the baryonic object. Really it is just the pressurization of dark matter against the baryonic matter's magnetism.

The magnetic field planets/planetoids:
Many of the planets have a magnetic field. This field is called the magnetosphere. Any of the spinning massive bodies has magnetism if it has a warm metalic core. These magnetic fields repel dark matter at a much greater rate than the baryons alone.

The non-magnetic field planet/planetoids:
The general density of an object's baryons has magnetism. This inherit magnetism causes dark matter to repel. But not nearly as much as the magnetic field. The lunar surface shows differentials in gravity to the topology [Cite:A. S. Konopliv].

The massive gas giants have cores that are magnetic. The magnetic field has been examined by NASA and others. The curvature of the space/time around Jupiter is far greater than the mass of the planet alone.

Tuesday, July 1, 2008

A day in the life of an Alpha Particle.

Here I am going to describe the importance Alpha Particles play in the interaction between dark matter and baryonic matter. We will theoretically follow a few particles from when they are emitted from the star to their end of life.

Our star has been burning for a few years now since it winked into existence. Nothing has really changed.

An Alpha particle is emitted from 15 degrees off the south pole of the star. It travels with all the other particles in a straight line to just past .1 au and it starts hitting resistance from the other alpha particles that have previously encountered the dark matter. These particles form a river of alpha particles that includes all the particles from 0>n>15deg. This river goes in a straight line until it again hits resistance from dark matter.

Alpha particle triptych
Degree from pole Theta:: Distance traveled before hitting resistance from dark matter
0>θ>15:: >.1 au
θ = 55:: ~.4 au
θ = 75:: ~.75 au
θ = 80:: ~1 au
θ = 85:: ~2 au
θ = 87:: ~3 au
θ = 88:: ~40 au
θ = 88.1:: ~100 au
θ = 89:: ~20000 au
θ = 89.5:: ~50000 au

This data is for explanation purposes only.
Testing is required for validation.
This torus shape surrounds the star. This is not a standard torus. It looks like M104. This galaxy has a bulbous core, but the galaxy extends along the equator. Our star exhibits similar properties. Our star is bulbous in the inner planetary core, which extends to just past 3 au. Its equatorial region extends past the ice clouds 50000+ au.

Particles emitted closer to the poles encounter dark matter resistance earlier and start changing direction to the outline of the torus towards the equator. This causes a river effect of charge particles along the baryonic side of the barrier between the dark matter and the baryonic matter.

An Alpha particle emitted from near the pole of the star (<~1 degree) will almost immediately encounter dark matter. There is an asymptotic behavior to the star’s emission of baryonic radiation. The star exhausts high energy non-baryonic sub-atomic particles from the other side of the asymptote closest to the pole.

Our alpha particles die when they crash into hydrogen or helium gas between 20000 and 50000+ au. The interesting thing here is, there is a possibility of Neucleosynthesis here in the outer region of our solar system. As Alpha particles collide with H or He they become heavier elements. For example three Alpha particles can fuse together to form a nucleus of a Carbon-12 ion(Stellar Nucleosynthesis). Free electrons would be attracted to complete the atom. These heavier particles fall again back towards the sun based on their density and angular momentum.

Other particles; Beta, Gamma, photons, are all examples of non-baryonic matter and pierce through the dark matter.

(7/30/08)addendum:: This pattern of alpha distribution will also account for mercury's orbit. Mercury will never fall into the sun because alphas push dark matter down away from the sun, at the asymptote. Thus the planet cannot fall up into the sun.