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From Wildbison

In the quantum vacuum there are many temporary acceleration vectors of mean scale a randomly oriented. The vectors going with the frame appear diminished, if the vacuum is viewed from an frame, and the vectors going against the frame appear improved, resulting in a net polarization of the vacuum. If the frame's acceleration g is small, the result is linear, and if the machine is filled up with vectors the coefficient of the polarization is likely to be unity. The conventional exponential term for controlling high-energy variations must also be reproduced. Thus the vacuum polarization is gary exp (g/a). The terms of the exponent when multiplied by the dipole moment have the dimensions of power.

The rest frame of the universe, as an example, is accelerated regarding local inertial frames that fall into the middle. In this rest frame the vacuum appears polarized and promotes the galaxy's gravitational field g. So we've

g= -GM/r2 + g exp (g/a)

where g is thought as bad. For g much greater than a, the exponential is negligible and Newton's law effects. However for g less than a, the exponential can be expanded to at least one + g/a and we get

g2 = aGM/r2

This really is exactly the method found empirically by Milgrom to spell out the motion of stars and galaxies in the weak-field region, except the law of gravity is changed, not the law of motion (Scientific American, August 2002). He sees that an is approximately one Angstrom per second squared, which is close to the "surface gravity" of an, the field of a mass at one meter, or the field of a galaxy in its outer parts. Also, the square of a is not far from the value of the cosmological constant, in units where c=1. In the saturated field strength of the quantum vacuum this model, a could be viewed.

The findings may be acceptably explained by utilising the proper quantum law of gravity and assuming a possible amount of ordinary matter M. There is no need for dark matter.

The resulting clear polarization could improve the acceleration, and indeed might cause the acceleration, when the process has started, due probably for some disturbance sometime ago, as area increases away from us. The same approach would improve the collapse, if space is collapsing in certain remote area. Therefore the cosmos may include distributed regions of development and collapse. A huge bang could result as virtual particles are ripped out of the machine, when development becomes intense. A collapsing region could produce a big crisis, where matter is crushed back into the machine. The entire process is presumably eternal and infinite. [ Travis-Online.Com Birthday Project 2010]