Perturbative study of wave function evolution from source to detection of a single particle and the measurement
- URL: http://arxiv.org/abs/2412.15409v4
- Date: Mon, 10 Feb 2025 15:26:28 GMT
- Title: Perturbative study of wave function evolution from source to detection of a single particle and the measurement
- Authors: Li Hua Yu,
- Abstract summary: We consider an extra aperture slit between the two slits to probe the evolution of the wave function.
When all the slits are long and thin, the 1D Schroedinger equation gives the wave function evolution until the final detection.
We show this function is real-valued, with amplitude and phase information, and is closely related to the wave function.
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- Abstract: We analyze the evolution of a particle wave function when it propagates through free space in the longitudinal z-direction from a thin entrance slit to a detector behind a thin exit slit parallel to the horizontal y-axis. We consider an extra aperture slit between the two slits to probe the evolution of the wave function and close the aperture slit starting from wide open until the detection counting rate in a repeated experiment drops to half. When all the slits are long and thin, the 1D Schroedinger equation gives the wave function evolution until the final detection. The width of the aperture slit in the vertical x-direction depends on the z-position of the slit providing an approximate description of the wave function evolution. The width of the function characterizing this dependence starts from the entrance slit. It grows wider until it reaches a maximum and then shrinks narrower and finally collapses into the exit slit where the particle is detected. Thus the envelope of this function has a spindle shape with its pointed ends at the two slits. Hence it is very different from the well-known wave function of the Schroedinger equation with the initial condition at the entrance slit, which is narrow only at the beginning, then grows wider until it reaches the exit slit, where it is much larger than the slit width. However, the phase information is lost because the aperture slit distorts the wave function. To keep the phase information, we replace the aperture slit with a thin pin (parallel to the y-axis) that blocks the wave function. We then study its perturbative effect on the counting rate of the detector. This analysis provides a function to probe the process of the wave function collapse right before the detection. We show this function is real-valued, with amplitude and phase information, and is closely related to the wave function.
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