08 December 2024

Periodicity and Phase Shift Dynamics between the Big Bang and Planck Time: A Micro-Scale Approach to Frequency and Time Shifts.


Soumendra Nath Thakur
ORCiD: 0000-0003-1871-7803
Correspondence: postmasterenator@gmail.com
DOI: http://dx.doi.org/10.13140/RG.2.2.29274.25285

December 08, 2024

Abstract:

This study investigates the applicability of micro-scale equations for frequency phase shift and time shift, specifically the equation T(deg) = x°/f·360°, which accounts for 1/360th of respective time periods, wavelengths, or energy values in standard units. The equation highlights its precision in analysing periodic phenomena at the Planck scale, with a focus on the Planck time (Tₚₗₐₙₖ) and its reciprocal relationship with Planck frequency and wavelength. By dividing the Planck time by a 1° phase shift of Planck time (1.498×10⁴⁶ seconds), a near-complete 360° phase cycle is observed, offering insights into the temporal structure of the universe and its origins from the Big Bang. This framework underscores the interconnectedness between time, wavelength, and energy, emphasizing the significance of phase relationships in cosmology.

Keywords:

Planck time, frequency phase shift, time shift, Big Bang, micro-scale, periodicity, phase cycle, Planck units, wavelength, energy, cosmology, temporal structure, phase relationships

The power of the derived equation for frequency phase shift and time shift:

The applicability of the micro scale derived equations for frequency phase shift and time shift, capable of accounting for 1/360th of the respective time period, wavelength, or energy values when measured in standard units:

T(deg) = Δt = x°/f·360°

This derived equation showcases its power by providing a framework to calculate precise phase relationships in terms of time, wavelength, or energy values. This equation is applicable at the micro scale and is capable of accounting for 1/360th of these respective values when measured in standard units. This precision highlights its versatility in analysing the periodic nature of fundamental physical phenomena.

The Planck time (Tₚₗₐₙₖ) is a cornerstone of this framework, with its value defined as 5.391247(60) × 10⁴⁴ seconds. The divisor, 1.498×10⁴⁶ seconds, represents a 1° phase shift of Planck time, emphasizing its relevance at the Planck scale. Within the domain of Planck units, fundamental constants interrelate in a profound manner, allowing the Planck time to act as the smallest meaningful unit of time, while the Planck frequency (fP) serves as the highest possible frequency. This reciprocal relationship underscores the fundamental periodicity and interconnectedness of these units.

In this context, the equation demonstrates that 1/360th of Planck time (Tₚₗₐₙₖ) aligns with 1/360th of the Planck wavelength (λₚₗₐₙₖ) and corresponds to 1/360th of the time period of Planck frequency. This alignment reinforces the inherent periodic structure embedded within the Planck units.

When dividing 5.391247(60) × 10⁴⁴ seconds by 1.498×10⁴⁶ seconds, the exact quotient is approximately 359.8963°, leaving a remnant of approximately 1.3427 × 10⁴⁶ seconds. This remnant, being nearly equal to the divisor, suggests that it can be divided approximately 360 times, reflecting a complete 360° phase cycle. This periodicity aligns closely with the foundational moment of t₀, the beginning of the Big Bang, offering a phase-oriented perspective on the temporal structure of the universe.

Human Perception of Zero and Hyper-Dimensions:

Human perception is inherently limited when dealing with abstract mathematical constructs such as zero and hyper-dimensions. A point, symbolized as '.', represents an exact spatial location without dimensionality, serving as a cornerstone of mathematical abstraction. Real numbers, extending infinitely in both positive and negative directions from zero on a one-dimensional number line, reflect precise mathematical consistency. Yet, translating these concepts into physical realities poses significant challenges.

For instance, humans struggle to perceive infinitesimally small values such as the Planck length (ℓP), far beyond the thresholds of perceptibility. Conversely, gamma rays, with detectable wavelengths of λ, highlight the stark disparity in scales that humans can observe. This limitation underscores the vast spectrum of physical phenomena lying outside direct human experience.

Furthermore, exploring hyper-dimensions beyond the familiar three-dimensional space introduces additional complexities. These dimensions defy intuitive comprehension, existing beyond conventional spatial boundaries. Despite these challenges, the interplay between zero, hyper-dimensions, and Planck-scale phenomena provides crucial insights into the fabric of the universe. By linking mathematical abstraction to physical realities, we gain a deeper appreciation of the intricate relationship between the observable and the imperceptible, paving the way for new frontiers in understanding the cosmos.

Conclusion

The derived equation for frequency phase shift and time shift underscores the periodicity inherent in Planck units. The calculation demonstrates that the Planck time (Tₚₗₐₙₖ) can be divided by a 1° phase shift of Planck time (1.498×10⁴⁶ seconds) approximately 360 times, completing a near-perfect phase cycle. This result reveals a fundamental periodic structure in the temporal framework of the universe, suggesting a profound interconnectedness between time, wavelength, and energy. The alignment of this framework with a 360° phase cycle offers a deeper understanding of the origins of the universe and its temporal dynamics, reinforcing the significance of phase relationships in cosmology.

Discussion

This study presents a ground breaking perspective on the temporal framework of the universe by leveraging micro-scale equations for frequency phase shift and time shift. This discussion delves into the implications, potential applications, and limitations of the research.

Implications for Cosmology

The equation offers a novel approach to understanding periodic phenomena at the Planck scale, where the foundational units of time, frequency, and wavelength are intricately interrelated. The study reveals that the Planck time (Tₚₗₐₙₖ) can be divided approximately 360 times by a 1 phase shift of Planck time, culminating in a near-complete 360 phase cycle. This finding introduces a periodic structure within the Planck units, aligning closely with the initial moments of the universe's existence, specifically the Big Bang.

This periodicity challenges traditional notions of continuous time by suggesting a discrete, cyclic framework at micro scales. Such a framework could refine our understanding of early-universe physics, offering insights into the transition from quantum-scale phenomena to macroscopic cosmological dynamics.

Bridging Mathematical Abstraction and Physical Realities

By integrating the analysis of hyper-dimensions and infinitesimal values with Planck-scale phenomena, the study addresses the inherent disconnect between human perception and abstract mathematical constructs. Human perceptual limitations hinder the direct observation of Planck-scale phenomena, yet the study bridges this gap by linking these imperceptible scales to observable cosmic phenomena, such as gamma rays. This connection underscores the importance of mathematical abstraction in unveiling the universe's hidden structures.

Exploring hyper-dimensions introduces additional complexity but offers a richer tapestry for understanding the interplay between time, space, and energy. The study’s findings, rooted in precise phase relationships, could inspire advancements in theoretical physics and quantum cosmology, enabling deeper insights into dimensions beyond our three-dimensional experience.

Applications in Modern Physics

1. Quantum Mechanics and Cosmology: The derived equation and its implications for phase cycles could enhance our understanding of quantum oscillations and their influence on large-scale cosmic phenomena.

2. Energy Distribution in Early Universe: The periodic structure of Planck time may inform models of energy distribution during the Big Bang, refining simulations of the universe’s origins.

3. Gravitational Wave Analysis: Insights from phase relationships could aid in the detection and interpretation of gravitational waves, particularly those originating from the early universe.

Limitations and Future Directions

While the study presents a compelling framework, its reliance on the precision of Planck-scale constants requires meticulous validation. The near-complete but imperfect 360 phase cycle raises questions about residual discrepancies and their physical interpretations. Additionally, extending this framework to include hyper-dimensional dynamics necessitates further exploration to ensure coherence with existing physical theories.

Future research could:

• Expand on the implications of the residual remnant (1.3427 × 10⁴⁶) in phase cycle calculations.

• Integrate these findings with quantum gravity theories to explore the unification of forces.

• Investigate experimental approaches for observing phase shifts at infinitesimal scales, potentially leveraging advancements in high-energy physics.

Conclusion

This study contributes significantly to our understanding of the temporal and periodic structure of the universe at its most fundamental level. By elucidating the interconnectedness between Planck units, time, and energy, it lays the groundwork for further exploration of the universe's origins and the profound relationship between mathematical abstraction and physical reality. The findings invite continued inquiry into the intricate dance of periodicity, energy, and dimensionality that defines the cosmos.

Reference:

[1] Thakur, S. N., & Bhattacharjee, D. (2023). Phase shift and infinitesimal wave energy loss equations - [v1]. www.preprints.org/manuscript/202309.1831/v1
[2] Thakur, S. N. Description of Planck Equation and Energy-Frequency Relationship. https://www.researchgate.net/publication/375416343
[3] Thakur, S. N. (2024). Unified Quantum Cosmology: Exploring Beyond the Planck Limit with Universal Gravitational Constants. Qeios, 26U31C https://doi.org/10.32388/26u31c
[4] Thakur, S. N. (2024). Why is 1° time interval (T) the smallest meaningful mathematical expression of the Planck frequency? ResearchGate https://doi.org/10.13140/RG.2.2.32358.40001
[5] Thakur, S. N. (2023). Quantum Scale Oscillations and Zero-Dimensional Energy Dynamics: ResearchGate. https://doi.org/10.13140/RG.2.2.36320.05124
[6] Thakur, S. N. (2023) et al. Energy Persistence Beyond Planck Scale. ResearchGate https://www.researchgate.net/publication/375488896/
[7] Thakur, S. N. Human's Imperceptions of Zero and Hyper-Dimension: Mathematical Abstraction and Physical Realities https://www.researchgate.net/publication/381514768

07 December 2024

A Revised Framework for the Photon-to-Dark-Energy Transition: Refining Photon Gravitational Dynamics


Soumendra Nath Thakur
December 07, 2024

Abstract:

This study presents a revised framework for understanding the photon-to-dark-energy transition, building upon Peter Rafay’s hypotheses and integrating concepts from Extended Classical Mechanics (ECM). The research extends classical and quantum principles to provide a more mathematically consistent and theoretically robust model of photon behaviour in gravitational fields, incorporating negative effective mass and gravitational dynamics. Central to the framework is the redefinition of photon mass as effective mass (Mᵉᶠᶠ), which allows for the exploration of photon interactions with gravity in terms of dark energy's properties, such as antigravitational effects. The key hypotheses proposed include the threshold frequency of electromagnetic radiation at Planck’s frequency, photon cessation under gravitational influence, and the transformation of photon energy into dark energy, which impacts gravitational dynamics without exhibiting motion.

Mathematical modelling plays a crucial role in the theoretical foundation, with relations such as the Planck-scale energy-frequency relation (E = hf) and energy-momentum exchange adapted to incorporate negative inertia. A force equation governing photon behaviour in gravitational fields, F = −Mᵃᵖᵖaᵉᶠᶠ, is derived, ensuring consistency with energy conservation and quantum principles. The study critiques and refines Rafay’s work, particularly the concept of photon cessation, replacing it with a model in which photon energy is transformed into dark energy, preserving the conservation of energy.

The research methodology incorporates quantum gravitational effects at the Planck scale and examines indirect observational data such as gravitational lensing and redshift to validate the model. The revised framework not only supports but strengthens the speculative aspects of Rafay’s hypothesis, offering a clearer and more comprehensive explanation of photon dynamics and the transition to dark energy. Future directions include experimental efforts to probe quantum gravity and further refinement of the photon-to-dark-energy transition, providing a unified approach to photon gravitational dynamics and cosmological acceleration.

Keywords: Photon Dynamics, Gravitational Interaction, Planck’s Frequency, Dark Energy, Planck Scale, Extended Classical Mechanics, Photon Energy Transition, Fundamental Constants, Quantum-Gravity Phenomena.

Soumendra Nath Thakur
ORCiD: 0000-0003-1871-7803
Tagore’s Electronic Lab, West Bengal, India
Correspondence:
postmasterenator@gmail.com, postmasterenator@telitnetwork.in
Declaration:
Funding: No specific funding was received for this work.
Potential competing interests: No potential competing interests to declare.

___________________________________________

Introduction

The interplay between photons and gravitational fields remains a cornerstone of modern physics, bridging concepts in quantum mechanics and general relativity. Despite extensive exploration, many questions surrounding the extreme behaviour of photons under gravitational influence remain unresolved. Central to these inquiries is the phenomenon of gravitational lensing and the broader implications of photon-gravitational interactions. This study delves deeper into these dynamics, proposing a novel perspective on photon behaviour at the Planck scale and its potential connection to dark energy.

One of the key hypotheses addressed in this research is the notion that photons, when subjected to photon-photon gravitational interactions, can cease oscillating at Planck's frequency. This cessation marks the transformation of photon energy into dark energy, a mysterious form of energy that exerts gravitational effects without associated motion or oscillation. Such a transition challenges conventional understandings of energy conservation and the role of fundamental constants like Planck’s length, Planck’s energy, and Planck’s frequency.

This work is grounded in Peter Rafay I’s theoretical framework, which asserts that Planck’s frequency represents the upper threshold of photon energy. Beyond this limit, photons can no longer sustain electromagnetic oscillations, thereby undergoing a transformation into a state consistent with dark energy. This transition not only redefines the behaviour of photons under extreme conditions but also introduces a potential pathway for understanding the enigmatic properties of dark energy—a phenomenon that governs the accelerated expansion of the universe.

The study examines the fundamental role of gravitational interactions in driving this transition, specifically focusing on the relationships among:

1. Planck’s constants and their interplay with photon energy and distance.

2. The cessation of oscillatory behaviour at critical thresholds.

3. The theoretical mechanics underlying the transformation of energy into a non-oscillatory, non-moving state.

Through this lens, we aim to construct a theoretical framework that connects photon dynamics to the cosmological implications of dark energy. By addressing these intersections, the research seeks to expand the boundaries of classical and quantum mechanics, offering insights that may contribute to the development of a unified theory of fundamental forces.

This introduction sets the stage for a detailed exploration of photon-gravitational interactions, emphasizing their relevance in both microcosmic and macrocosmic phenomena. As we move forward, we explore the mathematical and conceptual underpinnings of these processes, shedding light on the profound implications they hold for understanding the universe’s most fundamental mysteries.

Methodology

1. Theoretical Framework

The research methodology begins with the adoption of Extended Classical Mechanics (ECM), integrating concepts of apparent mass and gravitating mass to understand photon dynamics in gravitational fields. The work draws from both classical mechanics and quantum physics, extending classical principles to accommodate quantum effects at the Planck scale.

• Photon Effective Mass: The concept of effective mass (Mᵉᶠᶠ) for photons is central, drawing upon their energy-momentum relations. This redefinition of mass allows the study of photon interactions with gravity in a way that incorporates dark energy’s characteristics, such as negative apparent mass.

• Dark Energy and Apparent Mass: The interaction between photons and gravitational fields is modelled using the relationship between negative effective mass and gravitational dynamics, directly correlating photon behaviour with cosmological acceleration and dark energy effects.

2. Hypothesis Formulation and Key Claims

The study is structured around a series of key hypotheses based on Rafay's work and ECM:

• Threshold Frequency: The frequency of electromagnetic radiation reaches a limit at Planck’s frequency.

• Photon Cessation: The interaction between photons in gravitational fields results in the cessation of their oscillatory motion.

• Energy Transformation: Photon energy is hypothesized to transform into dark energy, which influences gravitational dynamics but does not exhibit oscillation.

• Gravitational Energy: Gravitational interactions at quantum scales are hypothesized to depend on the ratio of Planck's length to the distance between interacting objects, as well as the relative energies of those objects.

3. Mathematical Modelling

Mathematical modelling plays a critical role in grounding the hypotheses in rigorous physics, focusing on key relationships and quantum scale adjustments:

• Energy-Frequency Relation: The Planck-scale relation E=hf is employed to describe photon energy and its potential transition to dark energy.

• Energy-Momentum Exchange: The energy-momentum relation p = hf/c (de Broglie’s photon momentum) is extended to incorporate apparent mass (Mᵃᵖᵖ) and negative inertia.

• Planck’s Scale Relation: Utilizing the Planck length (ℓP) and Planck time (tP) through the equation ℓP/tP = c, the model incorporates the smallest meaningful scales where quantum gravitational effects dominate.

• Photon Dynamics and Force: A force equation, F = − Mᵃᵖᵖaᵉᶠᶠ, where aᵉᶠᶠ represents the effective acceleration due to gravitational fields, governs photon behaviour at the Planck scale.

4. Quantum Gravitational Interactions

Quantum considerations are introduced to refine gravitational dynamics, especially when energy and mass approach Planck’s limits:

• Threshold Frequency and Photon Behaviour: The threshold frequency at Planck’s frequency leads to modifications in photon behaviour, governed by quantum gravitational forces that can result in the cessation of oscillatory motion, as photons transition into dark energy.

• Gravitational Energy Modulation: At micro-scales, gravitational energy dynamics are heavily influenced by the ratio of Planck’s length to the distance between interacting objects. The energy threshold at which gravitational energy is affected by Planck-scale factors is explored.

5. Empirical and Observational Considerations

Though direct detection of quantum gravitational effects at the Planck scale is not currently feasible, the methodology incorporates indirect observational techniques:

• Gravitational Field Lensing and Redshift: These phenomena are analysed through the lens of photon dynamics in extended classical mechanics, particularly focusing on the energy exchanges that result from gravitational interactions.

• Cosmological Models: Dark energy’s effects on cosmic expansion and gravitational behaviour are modelled based on its negative effective mass and antigravitational properties.

6. Refinement of Rafay’s Hypothesis

The methodology critiques and refines Rafay’s work, addressing speculative aspects with a more rigorous framework:

• Photons and Dark Energy: The transformation of photon energy into dark energy is modelled not merely as a speculative hypothesis but as a transition governed by the relationship between effective mass and gravitational dynamics, thereby offering a consistent theoretical explanation.

• Photon Cessation: The claim of photon cessation due to gravitational interaction is reconsidered in light of the conservation of energy. Rather than ceasing, photon energy is transformed, adhering to established physical laws.

7. Model Validation and Consistency Checks

Consistency checks are carried out by comparing the predictions of the extended classical mechanics framework with existing astrophysical observations, such as the behaviour of galaxies under dark energy and the cosmic expansion rate. Additionally, mathematical consistency is ensured by ensuring the logical coherence of all derived equations with established physics principles (e.g., energy conservation, general relativity, and quantum mechanics).

8. Conclusions and Future Directions

The methodology concludes by synthesizing the findings of the theoretical framework with observational evidence, highlighting the unified theory of gravitational interactions. Future research directions focus on:

• Testing Quantum Gravity Models: Developing experimental methods to probe quantum gravitational effects at the Planck scale.

• Advancing the Photon-Dark Energy Transition: Further refinement of the mathematical models to explore the full implications of photon transition to dark energy in various astrophysical scenarios.

This methodology bridges classical mechanics, quantum theory, and cosmology, providing a unified approach to understanding photon dynamics, gravitational interactions, and dark energy, while addressing the speculative nature of existing hypotheses.

Theoretical and Mathematical Framework:

In the article "About the Gravitational Interaction of Photons," Peter Rafay explores the theoretical behaviour of photons under the influence of gravitational forces. The key findings of the study are:

1. The threshold frequency of electromagnetic radiation (photons) is equal to Planck's frequency.

2. Under the influence of gravity between photons, the radiation will cease, effectively stopping.

3. The energy of the photons will transform into what is termed 'dark energy,’ a form of energy that influences gravity but does not exhibit movement or oscillation.

4. Gravitational energy is influenced by the ratio of Planck's length to the distance between two interacting objects, as well as the ratio of the multiplied energies of two interacting particles to Planck’s energy, which are constants in nature.

Rafay’s work introduces a novel perspective on how gravitational energy can be influenced by fundamental constants and provides a theoretical framework for further research into the gravitational interactions of photons and the role of dark energy.

Extended Classical Mechanics Framework and Photon Dynamics

The series of research papers by Soumendra Nath Thakur delves into the extended classical mechanics framework, addressing various aspects of photon dynamics, gravitational interactions, and dark energy. Key highlights of these studies are as follows:

1. Extended Classical Mechanics: Vol-1 - Equivalence Principle, Mass, and Gravitational Dynamics:

This paper reinterprets the classical equivalence principle by integrating the concepts of Apparent Mass (Mᵃᵖᵖ) and Gravitating Mass (Mɢ). It extends the principle to include insights on both ordinary and dark matter, suggesting that negative apparent mass plays a crucial role in gravitational dynamics and aligns with modern research on dark energy.

2. A Nuanced Perspective on Dark Energy: Extended Classical Mechanics:

This work introduces the concept of effective mass (Mᵉᶠᶠ) for photons, reinterpreting their interaction with gravity. The study suggests that the negative effective mass, similar to dark energy's properties, leads to antigravitational effects, contributing to cosmic acceleration and offering a unifying perspective between quantum and cosmological phenomena.

3. Photon Dynamics in Extended Classical Mechanics:

This paper investigates the effective mass of photons and its implications for force interactions. By redefining photons' dynamics using effective mass, the study draws analogies between the photon’s behaviour and dark energy, offering insights into gravitational lensing, redshift, and the role of energy-momentum interactions.

4. A Symmetry and Conservation Framework for Photon Energy Interactions in Gravitational Fields:

This research examines the symmetrical energy exchanges between photons and gravitational fields, distinguishing between intrinsic photon energy (E) and gravitational-interaction energy (Eg). The paper highlights the importance of these energy components in understanding gravitational lensing, redshift, and photon behaviour within gravitational wells.

Together, these studies present an advanced framework of extended classical mechanics that bridges classical, quantum, and cosmological perspectives, offering new insights into photon dynamics, gravitational interactions, and the nature of dark energy. The work emphasizes the role of negative effective mass and gravitational energy in shaping the universe's fundamental forces and paves the way for future research in these areas.

Unifying Photon Gravitational Dynamics and Dark Energy within Extended Classical Mechanics

The research presented in my work builds upon linking dark energy to photon gravitational dynamics through the concepts of apparent mass and negative effective mass within the framework of extended classical mechanics. This approach integrates fundamental relations such as Planck’s Energy-Frequency Relation (E=hf), de Broglie Photon Momentum-Wavelength Relation (ρ=h/λ), and the Planck Scale Relation (ℓP/tP = c). These principles provide the mathematical foundation for understanding photon dynamics and their transition into dark energy.[1][2]

In contrast, Peter Rafay’s research, "About the Gravitational Interaction of Photons," proposes a speculative hypothesis in which photons, at Planck’s frequency, transform into dark energy. Rafay’s assertions highlight the following:[4]

1. Photons reach a threshold frequency equal to Planck’s frequency.

2. The gravitational interaction between photons causes them to cease oscillating.

3. Photon energy undergoes a transformation into dark energy.

4. This dark energy affects gravity but does not exhibit physical motion or oscillation.

5. Gravitational energy is influenced by the ratio of Planck's length and the distance between interacting objects, as well as the energies of interacting particles relative to Planck’s energy.

My own work, including the following studies:

1. Extended Classical Mechanics: Vol-1 - Equivalence Principle, Mass, and Gravitational Dynamics,

2. A Nuanced Perspective on Dark Energy: Extended Classical Mechanics,

3. Photon Dynamics in Extended Classical Mechanics: Effective Mass, Negative Inertia, Momentum Exchange, and Analogies with Dark Energy,

4. A Symmetry and Conservation Framework for Photon Energy Interactions in Gravitational Fields, provide a more mathematically consistent and theoretically robust framework that supports Rafay's hypothesis. I demonstrate that at the Planck length, photons become imperceptible, aligning with the characteristics of dark energy. My research offers a unified approach, grounded in extended classical mechanics and electromagnetic wave theory, which not only extends but clarifies and strengthens the speculative nature of Rafay's hypothesis. This work moves beyond mere speculation, offering a clear, consistent, and comprehensive explanation of the photon-to-dark-energy transition at the Planck scale.[5][6][7[8]

Mathematical and Conceptual Revisions

1. Threshold Frequency of Electromagnetic Radiation (Photon) and Planck Frequency

Rafay's assertion regarding the threshold frequency of photons at Planck’s frequency finds alignment in my research. However, the Planck frequency can be expressed mathematically as:

fP = c/ℓP

where c is the speed of light and ℓP is the Planck length. This frequency forms the upper limit of measurable electromagnetic radiation and situates photons at quantum scales, beyond which classical physics no longer holds.[1]

2. Photon "Cessation" and Gravitational Interactions

Rafay’s claim of photon cessation due to gravitational interactions contradicts energy conservation laws. In extended classical mechanics, this is addressed by modelling photon dynamics as follows:

F = − Mᵃᵖᵖaᵉᶠᶠ

where Mᵃᵖᵖ represents the apparent mass of the photon and aᵉᶠᶠ is the effective acceleration due to gravitational interaction. This formulation ensures that photons continue to exhibit behaviour consistent with energy conservation, even under extreme gravitational conditions.[6][8]

3. Photon Energy Transforming into Dark Energy

In contrast to Rafay’s claim, my research reinterprets the transition of photon energy into dark energy through the concept of negative effective mass. The equation for this transformation can be derived as follows:

Mᵉᶠᶠ = M + (−Mᵃᵖᵖ)

This describes the photon’s energy being transferred into an effective mass that influences gravitational dynamics. This relationship is crucial for understanding cosmic acceleration and the role of dark energy in shaping the universe.[5][6][7][8]

Conclusion: The integration of quantum-scale principles with classical mechanics offers a consistent framework for understanding photon dynamics in gravitational fields. By expanding on Rafay’s hypothesis through mathematical modelling, I present a comprehensive approach to the photon-to-dark-energy transformation, emphasizing the role of apparent mass and effective mass in gravitational interactions. This work refines the speculative nature of Rafay’s claims, providing a mathematically grounded explanation consistent with fundamental physical laws.

Discussion

The study presented examines the intersection of photon dynamics, gravitational interactions, and the nature of dark energy, bridging ideas from classical mechanics, quantum physics, and cosmology. By refining Peter Rafay's hypotheses on photon behaviour under gravitational influence, this work provides an advanced and mathematically consistent framework that not only supports but also strengthens and clarifies the speculative nature of Rafay’s ideas. In particular, it explores the potential transformation of photon energy into dark energy, a process that could offer new insights into the mysteries of the universe's accelerated expansion and the gravitational behaviour of photons.

The concept of photon-photon interactions, particularly at the Planck scale, is central to the research. Rafay’s hypothesis that photons cease oscillating when subjected to gravitational interactions is revisited and revised. While Rafay proposed that this cessation results in the transformation of photon energy into dark energy, this interpretation challenges conventional notions of energy conservation. The study offers a more refined perspective by introducing the idea of negative effective mass, which allows the energy of photons to be transferred into dark energy without violating energy conservation laws. This approach provides a coherent theoretical explanation, supported by mathematical models, that aligns with established principles of physics.

The research integrates the concept of effective mass (Mᵉᶠᶠ) for photons, which is central to understanding their behaviour in gravitational fields. By extending classical mechanics to incorporate quantum effects, the study successfully addresses the relationship between photon energy, gravitational fields, and dark energy. The negative effective mass, analogous to dark energy’s properties, leads to anti-gravitational effects that contribute to cosmic acceleration, providing a unified perspective on quantum and cosmological phenomena.

Rafay’s original idea of the threshold frequency, wherein photons reach a limit at Planck's frequency, is corroborated in the study, with the Planck frequency fP = c/ℓP, where c is the speed of light and ℓP is the Planck length, serving as the upper bound for photon energy. This insight is pivotal in understanding how photons behave at quantum scales and how they might transition into a state that influences gravitational dynamics without exhibiting movement or oscillation.

The reinterpretation of photon cessation is also crucial. In the original hypothesis, photons were said to cease oscillating due to gravitational interactions, a notion that contradicted the conservation of energy. By applying the framework of extended classical mechanics, the study demonstrates that photons continue to exhibit behaviour consistent with energy conservation, even at extreme gravitational conditions. The force equation F = − Mᵃᵖᵖaᵉᶠᶠ, where Mᵃᵖᵖ represents the photon’s apparent mass and aᵉᶠᶠ is the effective acceleration, ensures that photons’ energy persists, albeit in a transformed state that influences gravitational fields.

In terms of the photon-to-dark-energy transition, the research suggests that photon energy is not lost but rather transformed into a state that resembles dark energy through the concept of negative effective mass. This transformation is modelled mathematically by incorporating the relationship Mᵉᶠᶠ = M + (−Mᵃᵖᵖ), where M represents the mass of the interacting objects and −Mᵃᵖᵖ represents the negative apparent mass of the photon. This equation provides a theoretical foundation for understanding how photons might contribute to the dynamics of cosmic acceleration and the observed effects of dark energy.

Ultimately, the study emphasizes the importance of developing a unified theory that connects photon dynamics with cosmological phenomena such as dark energy and gravitational lensing. By expanding the framework of extended classical mechanics to incorporate quantum-scale interactions, the research presents a comprehensive model that provides deeper insights into the nature of the universe. It highlights the need for further exploration of these phenomena at both the theoretical and observational levels, with future directions focusing on testing quantum gravity models and advancing our understanding of the photon-dark-energy transition.

This work not only refines existing theories but also opens new avenues for investigating the interplay between gravity, photons, and dark energy, which could potentially lead to the development of a more unified theory of the fundamental forces in nature. Through its combination of classical mechanics, quantum physics, and cosmology, it provides a promising foundation for future research into the mysteries of the cosmos.

Conclusion

This study has explored the intricate relationship between photon dynamics, gravitational interactions, and the nature of dark energy, synthesizing ideas from classical mechanics, quantum physics, and cosmology. By extending Peter Rafay's hypotheses on photon behaviour under gravitational influence, a more mathematically consistent and theoretically robust framework has been developed, offering new insights into the photon-to-dark-energy transformation.

Through the introduction of the concept of effective mass (Mᵉᶠᶠ) for photons, this research has provided a comprehensive explanation for photon interactions in gravitational fields. Negative effective mass, akin to dark energy’s characteristics, was identified as a central factor in understanding cosmic acceleration and gravitational lensing, offering a unified perspective that bridges quantum and cosmological phenomena.

The study revisited Rafay’s proposition of photon cessation at Planck’s frequency, refining this idea within the constraints of energy conservation. Instead of ceasing, photon energy is hypothesized to transform into dark energy through the concept of negative effective mass, contributing to gravitational dynamics without violating established physical laws.

By modelling these interactions mathematically—through equations such as F = − Mᵃᵖᵖaᵉᶠᶠ and Mᵉᶠᶠ = M + (−Mᵃᵖᵖ) —the research provides a consistent theoretical framework that not only clarifies but strengthens the speculative nature of Rafay’s claims. This framework highlights the role of apparent mass and energy transformation in gravitational interactions, offering deeper insights into the role of photons in shaping the universe's fundamental forces.

In conclusion, this work lays the foundation for future research in photon-gravitational dynamics and dark energy. It proposes a unified theory that could lead to a deeper understanding of the universe’s accelerated expansion, gravitational lensing, and the nature of dark energy. As this theoretical framework continues to evolve, future studies will refine the photon-to-dark-energy transition and test quantum gravity models, potentially revealing new dimensions in our understanding of the cosmos.

References:

[1] Planck, M. (1914). The theory of heat radiation (Morton Masius, Trans.) [Book]. P. Blakiston’s Son & Co. https://www.gutenberg.org/files/40030/40030-pdf.pdf
[2] Dingle, H. (1941). Matter and Light: The New Physics. By Louis de Broglie. Translated by W. H. Johnston, B.A. (London: George Allen ’ Unwin, Ltd.1939. Pp. 300. Price 12s. 6d. net.). Philosophy, 16(62), 210–211. https://doi.org/10.1017/s0031819100002370
[3] Chernin, A. D., Bisnovatyi-Kogan, G. S., Teerikorpi, P., Valtonen, M. J., Byrd, G. G., & Merafina, M. (2013a). Dark energy and the structure of the Coma cluster of galaxies. Astronomy and Astrophysics, 553, A101. https://doi.org/10.1051/0004-6361/201220781
[4] Peter Rafay I. About the Gravitational Interaction of Photons. J Phys Astron. 2017; 5(3):130. https://www.tsijournals.com/articles/about-the-gravitational-interaction-of-photons-13560.html
[5] Extended Classical Mechanics: Vol-1 - Equivalence Principle, Mass and Gravitational Dynamics - [v3]. 202409.1190/v3. https://www.preprints.org/manuscript/202409.1190/v3
[6] Thakur, S. N. (2024). A Nuanced Perspective on Dark Energy: Extended Classical Mechanics. Preprints.org (MDPI). https://doi.org/10.20944/preprints202411.2325.v1
[7] Thakur, S. N. (2024). Photon Dynamics in Extended Classical Mechanics: Effective Mass, Negative Inertia, Momentum Exchange and Analogies with Dark Energy. Preprints.org (MDPI), 202411.1797.v1. https://doi.org/10.20944/preprints202411.1797.v1
[8] Thakur, S. N. (2024). A Symmetry and Conservation Framework for Photon Energy Interactions in Gravitational Fields. Preprints.org (MDPI), 202411.0956.v1. https://doi.org/10.20944/preprints202411.0956.v1

05 December 2024

Justification of Angular Representation in Time Dilation

December 05, 2024
Dear Mr. Andrew Marcu,
I appreciate the time and effort you've invested in reviewing my work and providing your detailed critique. Below, I address the concerns you raised, clarifying and reinforcing my research's scientific basis:
1. On Time Dilation and Presentation Consistency
You noted:
“The text asserts that t - t₀ > t′ − t₀ (correct for time dilation), then reverses this with t < t′, introducing internal inconsistency.”
However, your statement that t - t₀ > t′ − t₀ is "correct for time dilation" is itself incorrect. Time dilation enlarges the observed time t′, making t - t₀ < t′ − t₀. This aligns with t<t′, confirming there is no inconsistency in my presentation. The apparent contradiction you highlighted stems from a misinterpretation rather than an actual error in my argument.
2. Angular Representation of Time Scales
You argued:
“The attempt to represent time scales in angular terms (t×360°) is non-standard and lacks a clear physical justification.”
Contrary to your claim, the angular representation has clear foundations in both classical mechanics and wave theory. A standard clock face divides 360° into 12 segments, correlating to periodic cycles in timekeeping. Similarly, in wave mechanics, a full cycle spans 360°, with the time shift for an angular phase x° given as:
T(deg) = Δt = x°/f⋅360°.
This mathematical basis is neither arbitrary nor unconventional but extends directly from established principles. For a dilated time t′, this framework explains how standard clock designs fail to reflect dilation precisely, resulting in "errored" time readouts.
An alternative perspective to your disagreement, which states, 'angular terms (t×360°) is non-standard and lacks a clear physical justification,' is that this objection is unfounded. Structurally, a standard clock face divides 360° into 12 equal segments, assigning 30° to each hour (360°/12). When the minute hand completes a full rotation (360°), it marks one hour, directly correlating the clock’s full rotation to a single period, T=360°.
Similarly, in wave mechanics, a complete cycle of a sine wave spans 360° of phase, establishing a standard period T=360°. The frequency f of a wave is inversely proportional to its period T, expressed as T=1/f. For each degree of phase in a sine wave, the time shift per degree is given by:
T/360°, or equivalently (1/f)/360°
For a phase shift of x°, the corresponding time shift is:
T(deg) = Δt = (x°/f)/360
In the case of proper time t, a full oscillation corresponds to T=360, yielding Δt=0 by design. Under time dilation, however, Δt′>Δt, resulting in Δt′>0. For a 1° phase shift in Δt, the dilated interval becomes:
Δt′=(1°/f)/360°
For a general x° phase shift:
Δt′=(x°/f)/360°
Applying this concept to a clock, each hour segment, designed to measure proper time t, corresponds to exactly 30° (360°/12). If time dilation causes the interval to stretch to 361°, each segment would then measure approximately 361°/12≈30.08°, exceeding the clock’s designated 30° marking for proper time t.
As a result, the clock, which is calibrated for proper time, cannot accurately reflect the dilated time t′, leading to an “errored” time readout. This demonstrates the validity of angular representation as a practical and scientifically coherent method to illustrate time dilation.
3., Relevance of Classical Mechanics
You contended:
“The discussion of classical mechanics (Hooke’s law, mechanical stress) is irrelevant to relativistic time dilation.”
While relativity primarily addresses time dilation in non-inertial or gravitational contexts, classical mechanics provides insight into the practical implications of mechanical systems, including clock deformations under acceleration or stress. This connection bridges theoretical relativity with real-world clock behaviour, offering a holistic understanding of timekeeping inaccuracies.
4. On Relativity and Non-Inertial Effects
Your statement:
“The claim that relativity does not comprehensively account for forces during acceleration is incorrect.”
While relativity does account for non-inertial effects through proper time calculations, the interplay of such forces with classical mechanics during acceleration is often underexplored in practical applications. My work seeks to address this gap, offering a complementary perspective rather than negating relativity's achievements.
5. General Observations
You described certain phrases, such as "the time dimension originates from and returns to a common point," as vague. These are conceptual expressions aimed at stimulating further thought and should be understood as part of a broader discourse rather than definitive scientific assertions.
Invitation for Further Exploration
To delve deeper into the foundational concepts and evidence supporting my framework, I invite you to review the following research papers:
1. Phase Shift and Infinitesimal Wave Energy Loss Equations http://dx.doi.org/10.13140/RG.2.2.28013.97763
2. Relativistic effects on phaseshift in frequencies invalidate time dilation II http://dx.doi.org/10.36227/techrxiv.22492066.v2
3. Reconsidering Time Dilation and Clock Mechanisms: Invalidating the Conventional Equation in Relativistic Context: http://dx.doi.org/10.13140/RG.2.2.13972.68488
4. Re-examining Time Dilation through the Lens of Entropy: http://dx.doi.org/10.32388/XBUWVD
5. Standardization of Clock Time: Ensuring Consistency with Universal Standard Time http://dx.doi.org/10.13140/RG.2.2.18568.80640
6. Formulating Time's Hyperdimensionality across Disciplines http://dx.doi.org/10.13140/RG.2.2.30808.51209
I hope these works provide clarity and address the concerns you've raised. Should you have further questions or wish to engage in constructive dialogue, I am more than willing to elaborate.
Best regards,
Soumendra Nath Thakur