Post by Pincho Paxton on Nov 25, 2016 14:51:17 GMT
Axis are physics created by gravity collisions at points, and the correlating outflow of magnetism from this gravity collision... for example a snowflake fractal.
The snowflake is a good example of a gravity collision, because it introduces you to axis alignments, and heat propagation, and it obeys the rules of same sized sphere stacking, quantum tunnelling, and shows super conductivity. The snowflake shows the X/Z axis as a hexagon structure, and you can take that shape from the 2D structure of Newton's kissing number problem for same sized sphere stacking.
Sphere stacking has a lot to do with quantum physics because same sized sphere relate to equal energy propagation from points. Gravity collisions have to find an escape route through the area of least resistance, and that area will rotate about a point, because the area of least resistance is a cause that creates an effect which is the area of highest resistance. If you compare this to a sliding 15 square puzzle then the area of least resistance is the hole, but the hole is then filled by a square, so now the area of least resistance has rotated. The outflow of gravity is magnetism, and it rotates around a point, because the area of least resistance rotates around a point when gravity collides... you get a sort of plasma ball. The empty square in the 15 square puzzle is the area of least resistance, and that compare to an electron. The electron is an empty hole that quickly fills with gravity as a spin to create a torus. The torus quickly creates a spin which is a quantum tunnel, and the quantum tunnel is magnetism which propagates gravity through a tube. The tube of gravity is bonding.
So we start with a snowflake fractal as a gravity collision in the X/Z axis with bonding tubes moving outwards from 6 points due to same sized stacking rules, and quantum tunnelling with rotating electron torus.
The Y axis of a snowflake is in the middle of the snowflake, it is taken up by the Y axis flowing towards the Earth, so you mostly only see the X/Z hexagon shape which has bonding of water towards points. Sometime you see a snowflake shaped like a Star Wars Tie Fighter. Two X/Z axis combine to make this Tie Fighter construction, you also get to see some Y axis propagation which is linear. In this case the Y axis has become locked with a second gravity collision just above the first gravity collision. It is this locking together of X/Z axis in pairs that sends out Quasar jets from galaxies. Once gravity is propelled into a jet it can collide to make a new galaxy as flat as the first galaxy.
The Earth makes the Y axis linear, because electrons are rotated about the Earth like golf ball dimples. Electrons rotate with gravity, and with an observer.
When you push a shovel through the ground it is the rotation of bonding of the X/Z axis that give resistance to the shovel movements in the y axis. The Y axis will rotate with the shovel movements, and you are trying to push the shovel through an alignment with the bonding axis. Earthquakes are most severe through an alignment of the bonding axis...
Fault curvature may control where big earthquakes occur
When you throw a ball it rotates with the Y axis propagation towards the Earth, and the rotation makes the Earth into a spherical shape... sorry flat Earthers.
If you believe in a flat Earth then you would have to explain why the Earth does not rotate with the Y axis the same as everything else on Earth does. You can explain flat objects on Earth...
...The snowflake for example is a flat shape because gravity is colliding at a point with the Y axis used up by gravity towards the Earth.
You can explain flat objects in the Universe...
...A Galaxy is flattened by opposing gravity collisions from two directions unlike the Earth with multiple gravity flow directions. A galaxy cannot rotate gravity so easily as it is in the Tie Fighter formation with another galaxy.
Electrons rotate with gravity collisions towards the area of least resistance.
Axis are fractals created by the magnetic outflows of the gravity collisions, and relate to same sized sphere stacking rules.
So here I have explained a lot of the mechanics of bonding, and axis rotation.
Pincho Paxton
The snowflake is a good example of a gravity collision, because it introduces you to axis alignments, and heat propagation, and it obeys the rules of same sized sphere stacking, quantum tunnelling, and shows super conductivity. The snowflake shows the X/Z axis as a hexagon structure, and you can take that shape from the 2D structure of Newton's kissing number problem for same sized sphere stacking.
Sphere stacking has a lot to do with quantum physics because same sized sphere relate to equal energy propagation from points. Gravity collisions have to find an escape route through the area of least resistance, and that area will rotate about a point, because the area of least resistance is a cause that creates an effect which is the area of highest resistance. If you compare this to a sliding 15 square puzzle then the area of least resistance is the hole, but the hole is then filled by a square, so now the area of least resistance has rotated. The outflow of gravity is magnetism, and it rotates around a point, because the area of least resistance rotates around a point when gravity collides... you get a sort of plasma ball. The empty square in the 15 square puzzle is the area of least resistance, and that compare to an electron. The electron is an empty hole that quickly fills with gravity as a spin to create a torus. The torus quickly creates a spin which is a quantum tunnel, and the quantum tunnel is magnetism which propagates gravity through a tube. The tube of gravity is bonding.
So we start with a snowflake fractal as a gravity collision in the X/Z axis with bonding tubes moving outwards from 6 points due to same sized stacking rules, and quantum tunnelling with rotating electron torus.
The Y axis of a snowflake is in the middle of the snowflake, it is taken up by the Y axis flowing towards the Earth, so you mostly only see the X/Z hexagon shape which has bonding of water towards points. Sometime you see a snowflake shaped like a Star Wars Tie Fighter. Two X/Z axis combine to make this Tie Fighter construction, you also get to see some Y axis propagation which is linear. In this case the Y axis has become locked with a second gravity collision just above the first gravity collision. It is this locking together of X/Z axis in pairs that sends out Quasar jets from galaxies. Once gravity is propelled into a jet it can collide to make a new galaxy as flat as the first galaxy.
The Earth makes the Y axis linear, because electrons are rotated about the Earth like golf ball dimples. Electrons rotate with gravity, and with an observer.
When you push a shovel through the ground it is the rotation of bonding of the X/Z axis that give resistance to the shovel movements in the y axis. The Y axis will rotate with the shovel movements, and you are trying to push the shovel through an alignment with the bonding axis. Earthquakes are most severe through an alignment of the bonding axis...
Fault curvature may control where big earthquakes occur
When you throw a ball it rotates with the Y axis propagation towards the Earth, and the rotation makes the Earth into a spherical shape... sorry flat Earthers.
If you believe in a flat Earth then you would have to explain why the Earth does not rotate with the Y axis the same as everything else on Earth does. You can explain flat objects on Earth...
...The snowflake for example is a flat shape because gravity is colliding at a point with the Y axis used up by gravity towards the Earth.
You can explain flat objects in the Universe...
...A Galaxy is flattened by opposing gravity collisions from two directions unlike the Earth with multiple gravity flow directions. A galaxy cannot rotate gravity so easily as it is in the Tie Fighter formation with another galaxy.
Electrons rotate with gravity collisions towards the area of least resistance.
Axis are fractals created by the magnetic outflows of the gravity collisions, and relate to same sized sphere stacking rules.
So here I have explained a lot of the mechanics of bonding, and axis rotation.
Pincho Paxton