A side experiment that could yield important data for the science of cosmology

One thing that can be done as a secondary experiment is to set off the SMUT particle generator once every six months. You would compare the direction of the SMUT particles “motion” in to the position of the Sun as seen from Earth at six month intervals. You would measure the difference in angles every six months and use them to triangulate the centre of the universe as the SMUT particle is perceived to always be “traveling” in the opposite direction to the motion of the universe. This would mean a stream of SMUT particles would always point to the area the Big Bang took place in.  Having said that, modern theories about cosmology state that the universe has no centre, thus the most likely outcome would be that there would be no difference in the direction the SMUT particles. They would “travel” in the same direction without any any deviation no matter what time of year they were generated.

If there is some measurable difference in the direction of the SMUT particles, and we say there would not be any change, the information the side experiment gives could be used to help calculate the size of the universe and thus it’s mass, and also calculate Earth’s position in relation to the centre of the universe. Also in this side experiment having two layers of detectors is important because it would let us know if the SMUT particles appear to be accelerating or decelerating. This would tell us about the motion of Earth, the Sun, the Milky Way galaxy and the acceleration rate and current speed of the expanding universe. All of these phenomena would be immensely useful in cosmology.

The expected “intuitive” outcome many people would expect this experiment to have:

The result the experiment would most likely actually have:

It is possible to use SMUT particle as a free energy source

If the SMUT particle experiment were done using Microchannel plate detectors that absorb the SMUT particles and other particles that would be created instead of just detecting them, then the experiment would become an energy source. In conventional atomic experiments if a particle is created the energy you get back is always equal to the amount of energy used to create the particle in the first place. This conforms to the laws of energy conservation. With the SMUT particle experiment this is not the case. You would create the particles [SMUT or otherwise], but no energy is used to create it or make them “move.” By that I mean draw the virtual SMUT particle and other particles into our reality and the universe moves past them while it stays still. What would happen is that the particle are reduced back to energy when they hit the detectors in this variation of the experiment. The energy of the particle’s journey is added to the Microchannel plate detectors. The energy that the Microchannel plate detectors accumulate could be harvested and put to use. To summarize: The energy of the impact on the detectors was not part of the creation of SMUT particle and other particles or their “motion”, thus you are getting more energy out of the process than you put into it. Therefore it could be used as an energy source. We entitle this configuration of the apparatus of the SMUT experiment a Static mass reactor.

It is possible to use the SMUT particle as a navigation aid

This is an idea that will make any anime fan squeal with joy, particularly if they are into outer spaced themed anime. In many space opera anime there are devices that works as interstellar compasses. No matter where they are in space they always points in the same direction. They serve as a navigation aid. Even if the starship they are installed within had to undertake extreme maneuvers, the device would always point the same way. One could argue a gyroscopic compass could do that, but it is also possible to use the SMUT particle experiment in the same way. When a SMUT particle is generated it always appears to “travel” in the same direction. It will appear to move in the opposite direction to the expansion of the universe. Therefore if the experiment was set up on a starship it would appear that the SMUT particle would always be moving in the same direction, so it could be used in the same way as a compass. This would be achieved by comparing where the SMUT particle was generated in the experiment (a known fixed point) apparatus to where it is detected in the apparatus (again, a known fixed point). This would give a measurable line that works just like the needle of a compass, that is, always pointing in the same direction.