Quantum Gravity Might Explain Dark Matter

In the quantum vacuum there are numerous transient velocity vectors of mean magnitude a randomly oriented. The vectors going with the frame appear diminished, if the vacuum is considered from an frame, and the vectors going against the frame appear increased, producing 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 will undoubtedly be unity. The typical exponential term for suppressing high-energy changes must also be reproduced. Thus the vacuum polarization is h exp (g/a). The terms of the exponent when multiplied by the dipole moment have the dimensions of power. Identify more on a related web site by visiting http://qpathlete.com.

The rest frame of the universe, for example, is accelerated with respect to local inertial frames that belong to the middle. In this rest frame the vacuum looks polarized and enhances the galaxy's gravitational field g. So we have

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

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

g2 = aGM/r2

This is exactly the system found empirically by Milgrom to describe the motion of stars and galaxies in the weak-field region, except the law of gravity is altered, maybe not the law of motion (Scientific American, August 2002). He finds that an is approximately one Angstrom per second squared, which will be close to the surface gravity of an, the field of a mass at one meter, or the field of a galaxy in its external parts. Also, the square of a is not far from the value of the cosmological constant, in units where c=1. In this type, a might be seen as the saturated field strength of the quantum vacuum.

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

As space accelerates from us, the resulting clear polarization would enhance the acceleration, and indeed could potentially cause the acceleration, once the process has started, due probably to some interference sometime ago. Click this URL quantum performance to check up why to think over it. If space is collapsing in certain distant place, the same approach could improve the collapse. Therefore the cosmos may possibly include distributed regions of collapse and development. When extension becomes extreme, a big bang could result as digital particles are ripped from the vacuum. A place would make a big crunch, where matter is crushed back in the machine. The entire process is presumably infinite and eternal..