Quantum Trajectories

Aatucagg believes that the 2 slit experiment has different results depending on the type of universe in which the experiment is held. In the spacial universe all mass is in the form of light and exibit a wave nature. If the 2 slit experiment were conducted in the spacial universe, all mass would travel as a wave through one or more slits. However, conducting the 2 slit experiment would be impossible in the spacial universe since no matter exists to create plates or walls. In the temporal universe all mass is in the form of matter and exibit a particle nature. If the 2 slit experiment were conducted in the temporal universe, all mass would travel as a particle through one or more slits. However, conducting the 2 slit experiment would be impossible in the temporal universe since no space exists to create slits. In the expanding and contracting fractal universes all mass is in the form of matter and light, exibiting a particle-wave nature. If the 2 slit experiment were conducted in the expanding and contracting fractal universes, mass would travel as a particle through one slit and as a wave through 2 or more slits. Just as electrons jump from one orbit to another based on quantum energy levels, free eletrons, as well as any particle, travel through space along quantum trajectories. These quantum trajectories are contained between the interference pattern created by the particle's wave nature with itself when traveling through 2 or more slits. The temporal component of the particle's mass creates a wave. If the wave interacts with itself, then an interference pattern is created that affects the spacial component of the particle's mass. The spacial component of the particle's mass can only exist where the wave of the temporal component of the particle's mass does not cancel. Where the wave cancels out is called a trough and where the wave adds is called a crest. The particle can not exist where there is a trough in the waveform. The particle has a higher probability of existing the closer it is to the crest of the waveform. Therefore, quantum trajectories are contained within probability pathways. These probability pathways connect crests of the waveform that lie between the troughs of the waveform. The trajectory that the particle follows lies within one of these probability pathways. The troughs of the waveform can be represented by lines radiating out from a single point located equal distance between slits of similar size. The probability pathways of the waveform can be represented by wedge shaped regions that radiate out from a single point located equal distance between slits of similar size. At the edges of the probability pathways, the chance of finding a particle is zero. At the center of the probability pathway, the chance of finding a particle is maximum. A quantum trajectory can be contained within one or more probability pathways. This means that only certain trajectories through space are allowed for a given particle. Since, a particle can quantum jump along a trajectory from one probability pathway to another, Aatucagg refers to these trajectories as quantum trajectories. The heisenberg uncertainty principle applies to quantum trajectories. This principle states that locating a particle in a small region of space makes the momentum of the particle uncertain; and conversely, that measuring the momentum of a particle precisely makes the position uncertain. Aatucagg believes that particles can travel continuously along a quantum trajectory within a probability pathway, but can make discrete quantum leaps between probability pathways. In the single slit experiment, no portions of space contain the particle's waveform interacting with itself, so the particle obeys the laws of Newton and travels in a straint line. In the double slit experiment, portions of space contain the particle's waveform interacting with itself, so the particle no longer obeys the laws of Newton and travels along a quantum trajectory.

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Quantum Trajectories

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Quantum Trajectories

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Interference Pattern