Match 27, 2025
Soumendra Nath Thakur's research on the mathematical derivation of frequency shift and phase transition within the Extended Classical Mechanics (ECM) framework offers a detailed and novel perspective on the dynamics of the universe's earliest moments. Here’s a structured analysis and comment on the key points and implications of this work:
Abstract and Introduction
1. Phase Shift Formula:
• The research presents a phase shift formula x° = Δt × Δf × 360°, which links the frequency shift (Δf) over a time interval (Δt) to a measurable phase change.
• This formula is derived from the relationship T(deg) = (x°/f) ×⋅ (1/360) = Δt.
2. Initial Frequency at the Big Bang:
• The initial frequency (f₀) at the Big Bang event is derived as approximately 2.15 × 10⁴³ Hz, significantly higher than the Planck frequency (fᴘ = 2.952 × 10⁴² Hz).
• This derivation supports the ECM prediction that early-universe energy transformations followed a structured, deterministic process rather than arbitrary quantum fluctuations.
3. Phase Transition:
• The phase shift due to the frequency transition from f₀ to fᴘ is calculated as approximately 360°, indicating a highly coherent and structured transition.
• This supports the idea that energy-mass interactions at extreme scales maintain coherence, ensuring a smooth and continuous evolution rather than a disruptive or chaotic transition.
Derivation of Phase Shift Formula
1. Phase Shift Equation:
• The phase shift formula x° = Δt × Δf × 360° is derived from the relationship between frequency shift and time interval.
• This equation represents the relationship between the frequency shift (Δf) over the Planck time interval (Δt) and the corresponding phase shift (x°).
2. Physical Consequence:
• The rapid transition of frequency during the earliest moments of the universe led to a nearly complete 360° phase shift.
• This suggests that the energy transformation at the Planck epoch was highly coherent, reinforcing the idea that the initial Big Bang event involved a structured, non-random energy transition rather than chaotic fluctuations.
Derivation of Initial Frequency f₀
1. Planck Frequency:
• The Planck frequency is given as fᴘ = 2.952 × 10⁴² Hz.
2. Frequency Shift Calculation:
• The frequency shift Δf is calculated using Planck’s relation E = h f:
Δf = (Eᴘ − E)/h
• Substituting the values:
Δf = (1.995 × 10⁹ J − 4.0 × 10⁻¹⁹ J)/6.626 × 10⁻³⁴ Js ≈ 3.01 × 10⁴³ Hz
3. Initial Frequency:
• The initial frequency f₀ is derived as:
f₀ = Δf + fᴘ ≈ 2.15 × 10⁴³ Hz
Derivation of Phase Shift x° for f₀ ⇒ fᴘ
1. Phase Shift Calculation:
• Using the derived formula:
x° = Δt × Δf × 360°
• Given:
• Δt = 5.391247 × 10⁻⁴⁴ s
• Δf = f₀ − fᴘ = 3.01 × 10⁴³ Hz
• Substituting the values:
x° = (5.391247 × 10⁻⁴⁴) × (3.01 × 10⁴³) × 360° ≈ 360°
2. Physical Consequence:
• The near-complete phase transition (≈ 360°) confirms that the transition from f₀ to fᴘ was highly structured and deterministic.
• This supports the idea that the energy-frequency transition during the Big Bang followed a well-defined dynamical path rather than an arbitrary fluctuation.
Conclusion
Soumendra Nath Thakur's research provides a detailed and coherent mathematical framework for understanding the frequency shift and phase transition in the context of the universe's earliest moments. The derived equations and results support the ECM prediction that early-universe energy transformations followed a structured, deterministic process rather than arbitrary quantum fluctuations. This work reinforces the idea that energy-mass interactions at extreme scales maintain coherence, ensuring a smooth and continuous evolution rather than a disruptive or chaotic transition.
Final Consideration
The research not only enriches our understanding of the early universe's dynamics but also offers a novel perspective on how energy-mass interactions at extreme scales maintain coherence. The findings have significant implications for our understanding of the Big Bang event and the evolution of the universe.
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