Friday, July 18, 2008

The balloon and the lead ball: logic problem

Two objects of the same mass (1 kg), a lead ball and a helium balloon, released at the same time will not hit the earth at the same time. Gravity is based on density.

The lead weight is falling to its density level. If left alone it would over billions of years fall to the center of the earth.

The balloon is rising to its density level.

Interesting.

Thursday, July 17, 2008

Specific strange Gravity

I have never setup a problem like this before. I want to show the pressure on the water from the gas bubble.

I was thinking of lava tubes in the ocean at shallow depths. When C and S gasses are released from the surface their temperature instantly raises the temp of the H2O to several thousand degrees. So all particles inside the bubble are gasses; our carbon is >3550°C. Specific gravity within the bubble causes the particles to layer and cool according to density. When the Carbon temp drops below 3550°C it exits the gas bubble and floats in the ocean. Likewise when the Sulfur temp drops below 115.21°C it exits the gas bubble and falls. The sulfur falls because it is more dense than the H2O or Carbon. Some of our H2O bubble manages to cool to 105°C at the surface causing bubbles. The H2O is still a gas when entering the atmosphere and instantly cools to the air temperature. The H2O condenses to a liquid drop eight feet above sea level and is hit by a wave.

This is an example of temperature assisted density driven specific gravity. But here the particles are not falling to meet the more massive earth. They are rising to their level of density.

Tuesday, July 15, 2008

The face of the moon

Why does the one face of the moon always point to the earth? I think it is because that side of the moon is more dense and is falling faster than the back side.

I am going to think about that!!!

Sun's effect called Gravity

Everything in the solar system falls towards the sun. Baryonic radiation from the sun causes the dark matter to be pushed back. All the baryonic matter that is maintaining a correct angular momentum will maintain its current solar orbit minus the minor friction caused by the dark matter. This is like a marble in a bowl with the system in space.

Even on the earth. The baryonic effect of the earth does cause a deep run into the dark matter. The earth spins. This effect at the bottom of the earth's baryonic bowl effect on the dark matter will cause everything around the earth to fall towards the earth. If I move 3km/h I will still fall towards the earth. If I move 11.186 km/s then I have achieved enough angular momentum to fall away from the earth but now towards the sun.

This includes the moon. The moon is in equilibrium between falling towards the earth and falling towards the sun. The tides show this.

If a marble was shot from the earth, it would need to increase momentum to 42.1 km/sec to pierce the denser dark matter at 1au. If the marble were to try to escape the sun's baryonic effect on dark matter at a distance of ~10au, I would need to increase momentum to >~10 km/sec to pierce the dark matter. This shows that there is a distinct pressure field on the dark matter from the baryonic radiation.

This general shape of the effect of baryonic matter on dark matter as a squashed spheroid/torus shows a physical reason for different angular momentum at different points in the elliptical orbit.