Above is a simple model of the gravitational field. The field strength is displayed as a waveform on the right. If we wanted to be accurate, we would place the theoretically shortest (most blue shifted) wavelength down at the center of the earth, and the minima, with a frequency of zero, somewhere out at some theoretical infinity. For the purposes of this model I will be sticking with the visible wavelengths.

On the surface of the earth sits one of the magnets which make up the Large Hadron Collider. It is surrounded by its warped space field, as would be the case with any mass, and the field strength is the brownish color you would expect to see when an object was at the surface of the earth. On the right we see the correct location for that magnet in the gravitational field. If the field was able to properly sort that collider magnet according to its density, it would be down in that blue section somewhere below the surface of the earth.





The magnet is powered up and now the momentum field around the magnet has produced a field density equivalent to that of the green section below the surface. The magnet is now experiencing about 5 meters per second of acceleration, because the distance to its destination has decreased. The magnet continues to power up until reaching a point where for a moment the magnetic field is in agreement with the perfect blue zone down below. For that moment the magnet experiences zero G forces.





The problems for that magnet only become severe when that boundary is crossed, and then the field strength continues to increase, as the magnetic field comes into alignment with a location in the field below its correct location. Here the effects of the field strength increase dramatically, and the magnet begins to generate an unexpected negative G Force, a force of such great strength, it was actually able to break metal bolts.


You can see clear evidence for upward momentum being responsible for the collider damage in the following photographs. Magnetic fields do possess momentum as one of their fundamental properties, and it is my hypothesis that it was this momentum that was responsible for the damage to the collider. If this is correct, we should expect more interesting problems to develop in the future (extra bolts have been added onto the magnets to hold them down to the floor, but even movement of the magnet is enough to cause quenching of the superconducting field, and who knows what kind of bizarre events might occur because of that powerful negative G Force being generated in that place).