Soumendra Nath Thakur ORCiD: 0000-0003-1871-7803 Dated 23-03-2024
In the realm of quantum mechanics, the transition to higher dimensions often entails profound transformations in the behaviour of fundamental particles. Among these, the photon, a quantum of light, exhibits remarkable changes as it traverses into higher-dimensional states. A particularly striking phenomenon observed during this transition is the occurrence of a massive phase shift in the Planck frequency of the photon. This phase shift, often exceeding thousands of degrees, signifies a significant alteration in the oscillation pattern and quantum properties of the photon. In this discussion, we delve into the implications of such a massive phase shift for the Planck frequency as the photon transitions to the elusive 0th dimensional state. Through this exploration, we aim to unravel the intricate nature of dimensional transitions and their impact on fundamental particles in the quantum realm.
The transition of the photon to the 0th dimensional state entails a notable change in its frequency and phase characteristics. One of the key observations is the occurrence of a massive phase shift for the Planck frequency (fₚₗₐₙₖ) of the photon. Let's denote the magnitude of this phase shift as θ, measured in degrees.
θ = 2482.76°
This significant phase shift suggests a profound transformation in the quantum properties of the photon as it transitions to the 0th dimensional state. Such a deviation from its original phase angle implies an intricate interplay of quantum mechanics and dimensional transitions, shedding light on the complex nature of the quantum realm.
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