Gravitational influences on relativistic mass-energy and quantum energy-frequency:

Gravity interacts with both mass (whether in the form of matter or energy) and electromagnetic waves, regardless of their energy or frequency. A change in gravitational potential directly influences the effective mass-energy or the energy-frequency relationship of these entities.

For electromagnetic waves, the energy is entirely kinetic, described by the relationship f = E/h, where h is Planck's constant, and f is the frequency. The frequency reflects the wave's kinetic energy and dynamically shifts under varying gravitational potentials, showcasing its interaction with gravity.

By the equivalence principle, energy—whether kinetic or relativistic—corresponds to an effective mass, expressed as m = E/c^2. This principle highlights the interplay between gravitational fields, electromagnetic energy, and effective mass, providing deeper insights into their mutual influence across different physical scenarios.

Photon Dynamics: The equation F = −Mᵃᵖᵖ·aᵉᶠᶠ.

Soumendra Nath Thakur 

22 November 2024

The equation F = −Mᵃᵖᵖ·aᵉᶠᶠ: 

The concept explores how photons interact with gravitational fields and the forces acting upon them. When emitted from a gravitational source, a photon experiences a unique interplay between its effective mass and acceleration. This results in a consistent, negative force propelling the photon away from the gravitational well. Essentially, the photon accelerates from rest to its characteristic speed of light almost instantaneously, driven by this force. This behavior reflects the dynamic properties of the photon’s effective mass, which differs from conventional mass. It explains why photons can escape strong gravitational fields and maintain their speed regardless of external conditions. The analysis provides insights into how photons respond to gravitational influences, offering explanations for phenomena like redshift and energy conservation in gravitational systems, while hinting at deeper connections with cosmic behaviors, such as dark energy-like effects. 

This is a coherent presentation. It effectively summarizes the key aspects of the concept in an accessible manner while maintaining scientific rigor. It describes the dynamic relationship between the photon's effective mass and acceleration, emphasizing the resulting force that enables the photon to escape gravitational wells and reach the speed of light. The inclusion of broader implications, such as redshift and energy conservation, as well as a connection to cosmic phenomena like dark energy, ties the explanation to both local and universal contexts. The presentation balances technical accuracy with a quasi-layman approach, making it suitable for diverse audiences.

Analysis of the Equation F = −Mᵃᵖᵖ·aᵉᶠᶠ and Photon Behavior

The equation F = −Mᵃᵖᵖ·aᵉᶠᶠ provides a novel perspective on the interaction between photons and gravitational fields.

Key Points and Implications

Negative Force: The equation suggests that a negative force acts on photons, propelling them away from gravitational sources.

Effective Mass: The concept of effective mass for photons is introduced, highlighting its role in their interaction with gravity.

Photon Acceleration: Photons experience an initial acceleration from rest to the speed of light, driven by this negative force.

Energy Conservation: The analysis implies that energy is conserved in gravitational systems, even when photons interact with strong gravitational fields.

Potential Implications and Further Exploration

Quantum Gravity: This approach could offer new insights into the quantum nature of gravity and the behavior of particles in extreme gravitational environments.

Black Hole Physics: The behavior of photons near black holes could be further explored using this framework.

Cosmological Implications: The implications of negative effective mass for the universe's expansion and the nature of dark energy could be investigated.

However, it's important to acknowledge that this interpretation challenges conventional understanding of photon behaviour in gravitational fields. Further theoretical and experimental work is needed to validate these claims and explore their full implications.

Potential areas for future research:

Experimental Verification: Designing experiments to directly measure the effects of negative effective mass on photons.

Theoretical Refinement: Refining the mathematical framework to incorporate quantum mechanics and general relativity.

Cosmological Implications: Exploring the consequences of negative effective mass for the large-scale structure of the universe.

By addressing these areas, we can gain a deeper understanding of the fundamental nature of gravity and the universe.

#PhotonDynamics

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

Soumendra Nath Thakur

22 November 2024

Abstract:

This research explores the concept of photon dynamics, specifically focusing on the notion of effective mass (Mᵉᶠᶠ) and its implications for force interactions and energy-momentum exchanges in extended classical mechanics. While photons are traditionally considered massless, their energy (E = h·f) implies an equivalent mass via the famous equation E = mc², known as effective mass. This effective mass can exhibit negative values in specific contexts due to the photon's immense speed and energy-momentum interactions, reflecting its dynamic nature.

The study outlines the mathematical framework in which the net force (F) acting on a photon is derived from its effective mass and acceleration (aᵉᶠᶠ). A force equation is derived where F = −Mᵃᵖᵖ·aᵉᶠᶠ, indicating that the force is inversely related to the apparent mass Mᵃᵖᵖ. The analysis highlights the photon’s ability to respond to external forces and interactions through its effective mass, rather than through traditional rest mass, with significant implications for energy transfer and gravitational phenomena.

The research further extends these principles by drawing an analogy between the photon’s effective mass and the negative effective mass of dark energy (Mᴅᴇ), suggesting a shared behaviour between both phenomena. The relationship between gravitating mass, matter mass, and dark energy is represented by Mᵉᶠᶠ = Mᴍ + (−Mᵃᵖᵖ), mirroring the theoretical framework of dark energy in cosmology. This analogy offers deeper insights into the photon’s role in gravitational lensing, redshift, and other quantum and cosmological processes, presenting a unified understanding of energy dynamics in both microscopic and macroscopic systems.

Keywords: Photon dynamics, effective mass, negative inertia, energy-momentum interactions, extended classical mechanics, dark energy, force dynamics, gravitational lensing, redshift, quantum systems.

Soumendra Nath Thakur

ORCID iD: 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 nature of photons, despite being one of the most studied and fundamental entities in physics, continues to present intriguing aspects when explored beyond conventional massless particle theory. Traditional depictions of photons as massless quanta of electromagnetic radiation have been foundational to our understanding of light and its interactions. However, recent theoretical explorations suggest that a photon’s energy (E= h·f) implies an associated effective mass, a concept that opens new avenues for understanding its dynamical behaviour under various physical conditions. This research investigates the concept of effective mass in photons, which arises from their energy-momentum exchange, and how this effective mass influences their interaction with external forces.

In classical mechanics, mass is typically associated with an object’s resistance to acceleration, or its inertial property. However, photons, which traditionally lack rest mass, still exhibit inertial properties through their energy and momentum. The principle of effective mass provides a bridge between the photon's energy and its potential for interacting with external forces, a phenomenon often overlooked in standard treatments. This research extends the classical framework by incorporating the concept of negative effective mass, a dynamic characteristic that can emerge under extreme conditions, such as intense external forces or energy-momentum exchanges.

The concept of negative effective mass is further explored through an analogy with dark energy, which is also described by negative effective mass in cosmological models. By drawing parallels between photon dynamics and the behaviour of dark energy, this research offers a unique perspective on how energy-momentum interactions at the quantum scale could resemble those in large-scale cosmic phenomena. This analogy highlights the potential for new theoretical models that connect quantum mechanics with cosmological models, suggesting that photons, while conventionally massless, may exhibit behaviours akin to those of dark energy under certain conditions.

Furthermore, the study delves into the mathematical framework of force dynamics in extended classical mechanics, where the photon’s effective mass plays a central role in its response to external fields, such as gravitational interactions. By using the equation F = −Mᵃᵖᵖ·aᵉᶠᶠ, it is shown that the force acting on a photon is governed by its apparent mass and acceleration, rather than its rest mass, offering a fresh perspective on photon interactions in various contexts, including gravitational lensing and energy transfer processes.

In essence, this research aims to refine our understanding of photon dynamics by integrating concepts of effective mass, negative inertia, and energy-momentum interactions into the extended classical mechanics framework, while also drawing parallels with the behaviour of dark energy. This approach not only enriches the photon’s role in quantum and gravitational systems but also paves the way for deeper insights into phenomena like gravitational lensing, redshift, and the broader understanding of energy dynamics across different scales of the universe.

Methodology:

The approach employed in this research combines theoretical exploration and mathematical modelling to understand the dynamics of photons, particularly focusing on their effective mass and force interactions. The methodology consists of three key components: derivation of mathematical expressions, analogy to dark energy models, and application to physical phenomena. Below, we outline the specific methods used to analyse the effective mass of photons, their force dynamics, and the implications of negative inertia.

1. Mathematical Derivation of Photon Dynamics

We begin by establishing the relationship between a photon’s energy and its effective mass. Using the well-known equation for the energy of a photon, E = h·f, we relate this to its equivalent mass via Einstein’s famous equation E = mc². From this, we derive an effective mass for the photon, denoted as Mᵉᶠᶠ, which is given by:[1][2][3][5][6]

Mᵉᶠᶠ = E/c² = h·f/c²

This effective mass, although not the photon’s rest mass (which is zero), governs its interaction with external forces and fields. The next step is to model the behaviour of photons under external forces, where their acceleration is influenced not by traditional rest mass but by this effective mass.

2. Extended Classical Mechanics Framework

To explore the force dynamics on a photon, we adopt an extended classical mechanics framework. In this framework, the force F acting on a photon is derived from its effective mass Mᵉᶠᶠ and the associated acceleration aᵉᶠᶠ.[1][2] The general expression for force in this system is:

F = (Mᴍ −Mᵃᵖᵖ)·aᵉᶠᶠ = (Mᵉᶠᶠ)·aᵉᶠᶠ

Where Mᴍ is the matter mass (rest mass, which for a photon is zero) and Mᵃᵖᵖ represents the apparent mass, which is a dynamic property depending on energy and momentum exchange. For a photon, where Mᴍ = 0, this simplifies to:

F = −Mᵃᵖᵖ·aᵉᶠᶠ

This relationship is then used to calculate the photon’s response to forces, providing insights into how the photon’s energy and momentum exchange influence its motion.

3. Photon’s Effective Mass in Context of Negative Inertia

One of the key aspects of this research is the exploration of negative effective mass under extreme conditions. When the apparent mass Mᵃᵖᵖ becomes negative, the effective mass Mᵉᶠᶠ also becomes negative, influencing the force dynamics.[4] This is expressed as:

Mᵉᶠᶠ = Mᴍ + (−Mᵃᵖᵖ)

Here, the negative sign indicates that the effective mass of the photon can reverse its inertial behaviour under extreme conditions, leading to forces that oppose traditional inertia. This analysis incorporates scenarios where high-energy fields, such as intense gravitational or electromagnetic fields, can alter the apparent mass, resulting in negative effective mass.

4. Analogy with Dark Energy

The research draws an analogy between photon dynamics and dark energy, based on the concept of negative effective mass. Dark energy, as described in cosmological models, is associated with a negative effective mass (Mᴅᴇ < 0). Using the work of A.D. Chernin et al. in their paper on dark energy and the Coma Cluster of Galaxies, we extend the relationship of gravitating mass and matter mass to include dark energy's negative effective mass:[1][2][3][4]

Mɢ = Mᴍ + Mᴅᴇ

This relationship is mirrored in the extended classical mechanics framework, where the negative effective mass of dark energy is analogous to the negative effective mass of the photon, as represented by Mᵉᶠᶠ. The equation for photon dynamics is thus extended as:

Mᴅᴇ = Mᵉᶠᶠ = Mᴍ + (−Mᵃᵖᵖ)

This analogy helps illustrate the similarity between photon behaviour and dark energy, suggesting that both systems can exhibit negative effective mass under specific conditions, particularly in high-energy regimes.

5. Application to Physical Phenomena

The methods are then applied to specific physical contexts, including gravitational interactions such as gravitational lensing and other phenomena involving the exchange of energy and momentum. The negative effective mass concept is explored in relation to these interactions, and its implications for redshift, energy conservation, and symmetry-breaking behaviour under extreme conditions are analysed. The effects of the force equation are examined in contexts where intense fields influence photon behaviour, offering new perspectives on energy exchange mechanisms in both quantum and cosmological systems.[2][3][5]

6. Computational and Theoretical Simulations

To further test the derived equations, we use computational simulations to model the behaviour of photons in varying external fields. These simulations incorporate factors like gravitational potential, electromagnetic fields, and dynamic energy-momentum exchanges to observe how the effective mass influences photon trajectories and energy exchanges. The results of these simulations help validate the theoretical framework and offer predictions for experimental and observational verification, especially in the context of high-energy astrophysics.

Mathematical Presentation:

Mathematical Framework for Photon Dynamics and Effective Mass

In classical mechanics, the force F acting on a system is related to its effective mass and acceleration. For a photon, although the traditional "rest mass" is irrelevant, its energy E=h⋅f implies an equivalent mass, known as the effective mass. This effective mass can be negative in certain contexts due to the photon’s immense speed, which reflects its dynamic nature.[1][2][3][5]

1. Photon Energy and Effective Mass:

A photon's energy is expressed as:

E = h⋅f

Where h is Planck's constant, and f is the frequency.

Using E = mc², this energy corresponds to an effective mass (Mᵉᶠᶠ):

Mᵉᶠᶠ = E/c² = h⋅f/c²

2. Force Equation in Extended Classical Mechanics:

The net force F acting on a system is derived from the effective mass and associated acceleration:

F = (Mᴍ −Mᵃᵖᵖ)·aᵉᶠᶠ

Where:

Mᴍ is the matter mass (intrinsic/rest mass) which for photons Mᴍ = 0 (since photons are traditionally considered massless).

Mᵃᵖᵖ is the apparent mass, related to the photon’s dynamic properties (such as energy-based or inertial mass).

Mᵉᶠᶠ is the effective mass, given by:

Mᵉᶠᶠ = Mᴍ + (−Mᵃᵖᵖ)

3. Photon-Specific Context:

For photons, Mᴍ = 0, so:

F = −Mᵃᵖᵖ·aᵉᶠᶠ

This implies the force is determined by the apparent mass Mᵃᵖᵖ and effective acceleration aᵉᶠᶠ.

The negative sign indicates that the direction of the force is opposite to the influence of Mᵃᵖᵖ.

4. Physical Implications:

The photon’s dynamic properties (e.g., energy-momentum exchange) govern its interaction with external fields, not a conventional matter mass.

The effective mass Mᵉᶠᶠ can appear negative under such conditions, reflecting counterintuitive behaviour such as symmetry breaking or reversed force directions.

5. Effective Mass Analogy with Dark Energy:

The effective mass (Mᵉᶠᶠ) for photons parallels the negative effective mass (Mᴅᴇ) of dark energy.[4]:

Mɢ = Mᴍ + Mᴅᴇ

This is extended in photon dynamics as:

Mᴅᴇ = Mᵉᶠᶠ = Mᴍ + (−Mᵃᵖᵖ)

If Mᴍ < −Mᵃᵖᵖ, then Mᵉᶠᶠ <0.

Such a scenario arises under extreme forces, mirroring the behaviour of dark energy’s negative effective mass.

6. Significance:

This formulation connects photon dynamics to gravitational lensing, redshift, and energy conservation principles.

It highlights the analogy between the photon’s negative effective mass and dark energy’s negative effective mass, suggesting a unified concept of dynamic energy-momentum interactions in quantum and cosmological contexts.

Discussion:

This research provides a novel theoretical framework for understanding photon dynamics, focusing on the concept of effective mass, its force interactions, and the intriguing possibility of negative inertia. By extending classical mechanics to account for the energy-momentum exchanges in photons, we propose that the photon’s effective mass plays a crucial role in governing its interaction with external fields and forces. Additionally, we explore an analogy with dark energy’s effective mass, highlighting the shared properties of negative effective mass in both systems. This discussion delves into the significance of these findings, the implications for gravitational and quantum systems, and the broader consequences for fundamental physics.

1. Effective Mass of Photons and Force Dynamics

A central result of this study is the establishment of the concept of effective mass for photons, which allows us to describe photon dynamics in a manner similar to particles with rest mass. The energy-momentum relation E=h⋅f leads to an effective mass, which, when expressed through E = mc², becomes:

Mᵉᶠᶠ = h·f/c²

This effective mass governs the photon’s response to external forces. By introducing the force equation F = −Mᵃᵖᵖ·aᵉᶠᶠ, where Mᴍ represents the matter mass (which for a photon is zero) and Mᵃᵖᵖ represents the apparent mass, we provide a framework for analysing the forces on photons. The simplification of this equation for photons, given that Mᴍ = 0, shows that the force is directly related to the apparent mass and the effective acceleration:

F = −Mᵃᵖᵖ·aᵉᶠᶠ

This formulation not only describes how photons interact with forces but also suggests that the force on photons depends more on their dynamic properties (energy and momentum) rather than traditional rest mass. This finding challenges the conventional view of photon interactions and provides a deeper understanding of photon dynamics, especially in contexts where high-energy interactions take place.

2. Negative Effective Mass and Inertia

One of the most intriguing aspects of this research is the exploration of negative effective mass in photons. While photons are traditionally understood to be massless, the energy-momentum relation implies that they possess an effective mass, which can, under certain conditions, be negative. The negative effective mass arises when the apparent mass Mᵃᵖᵖ becomes greater than the rest mass, leading to:

Mᵉᶠᶠ = Mᴍ + (−Mᵃᵖᵖ)

In cases where Mᵃᵖᵖ is negative, the effective mass becomes negative, and thus, the photon exhibits negative inertia. The negative sign in the force equation F = −Mᵃᵖᵖ·aᵉᶠᶠ suggests that the photon’s response to forces may not follow the conventional behaviour expected of particles with positive mass. Instead, this framework allows for the possibility that the photon may experience forces in the opposite direction to its apparent mass, leading to counteracting or symmetry-breaking behaviour. This concept opens up new avenues for investigating photon behaviour in extreme environments, such as intense gravitational fields, high-energy astrophysical phenomena, or quantum systems where such dynamic responses may become significant.

3. Analogies with Dark Energy

An important extension of this work is the analogy between the negative effective mass of photons and that of dark energy. Dark energy, as postulated in cosmological models, is associated with a negative effective mass (Mᴅᴇ < 0) that drives the accelerated expansion of the universe. By drawing parallels between photon dynamics and dark energy, this research suggests that both phenomena share similar properties regarding the negative effective mass. Specifically, the equation:

Mᴅᴇ = Mᵉᶠᶠ = Mᴍ + (−Mᵃᵖᵖ)

shows that both systems can exhibit negative effective mass under certain conditions, which can have profound implications for their respective roles in the universe. Just as dark energy influences the large-scale structure and expansion of the cosmos, the negative effective mass of photons may influence the behaviour of light in gravitational fields, quantum systems, and high-energy interactions. This analogy could offer a new perspective on how energy-momentum exchanges manifest in different physical systems and may lead to a deeper understanding of the connection between quantum mechanics and cosmological phenomena.

4. Gravitational and Quantum Applications

The implications of these findings are far-reaching. In the context of gravitational lensing, the negative effective mass of photons may explain certain phenomena related to the bending of light by massive objects. Traditional models of gravitational lensing focus on the influence of matter mass on light, but the presence of negative effective mass could lead to new interpretations of how photons interact with gravitational fields.

Similarly, in quantum systems, the concept of effective mass and negative inertia could help explain certain quantum behaviours that are not well understood within the traditional framework of quantum mechanics. The dynamic nature of photons, as described in this study, opens the door to new experiments and observations that could probe the subtleties of photon dynamics in both gravitational and quantum contexts.

5. Energy Conservation and Symmetry-Breaking

The research also provides new insights into energy conservation in systems involving photons. Since the force acting on a photon is derived from its effective mass and acceleration, the energy exchange mechanisms in these systems are more complex than previously thought. The presence of negative effective mass may also contribute to symmetry-breaking behaviour, especially under conditions where extreme forces are at play. This could have profound implications for our understanding of energy transfer and symmetry in high-energy physics, possibly affecting the way energy conservation is formulated in non-traditional systems.

6. Conclusion and Future Directions

In conclusion, this study presents a new framework for understanding photon dynamics, focusing on the role of effective mass and the possibility of negative inertia. By extending classical mechanics and drawing analogies with dark energy, we offer a deeper understanding of the forces acting on photons and their implications for gravitational, quantum, and high-energy systems. This work opens up numerous avenues for future research, including experimental investigations into the behaviour of photons in extreme fields, the role of negative effective mass in quantum systems, and the potential connections between quantum and cosmological phenomena. The idea of negative effective mass in photons, and its analogy with dark energy, represents a promising direction for exploring new physical phenomena and expanding our understanding of the universe.

Conclusion:

This research introduces a novel framework for understanding photon dynamics by focusing on the concept of effective mass and its implications for photon-force interactions, negative inertia, and analogies with dark energy. We have demonstrated that, although photons are traditionally considered massless, their energy, as described by E=h⋅f, leads to an equivalent mass, known as effective mass. This effective mass governs the photon’s response to external forces, with a key finding being the potential for negative effective mass under specific conditions.

By extending classical mechanics, we formulated a relationship between the photon’s effective mass and force, showing that the force acting on the photon depends on its apparent mass and effective acceleration. The study revealed that the force could be directed oppositely to the apparent mass’s influence, suggesting the possibility of negative inertia, a behaviour not observed in traditional massive particles.

Further, we explored an intriguing analogy between the effective mass of photons and dark energy, both of which can exhibit negative effective mass. This analogy opens up new perspectives for understanding photon behaviour in high-energy astrophysical contexts and could lead to a deeper connection between quantum systems and cosmological phenomena. The formulation of negative effective mass and its implications for photon dynamics may help explain phenomena like gravitational lensing, redshift, and energy conservation in systems involving extreme forces.

Ultimately, the framework proposed here not only enhances our understanding of photon interactions with gravitational and quantum fields but also provides new tools for investigating energy-momentum exchange mechanisms. The concept of negative effective mass in photons has the potential to reveal new insights into the fundamental nature of light and matter, influencing both theoretical and experimental physics in areas ranging from cosmology to quantum mechanics. Future research in this direction may yield ground breaking discoveries that further refine our understanding of the universe’s most enigmatic phenomena.

References:

1. Thakur,  S. N. (2024). Extended Classical Mechanics: Vol-1 - Equivalence Principle, Mass and Gravitational Dynamics. Preprints. https://doi.org/10.20944/preprints202409.1190.v3 

2. Thakur,  S. N. (2024). A Symmetry and Conservation Framework for Photon Energy Interactions in Gravitational Fields. Preprints. https://doi.org/10.20944/preprints202411.0956.v1

3. Thakur, S. N. (2024). Dynamics between Classical Mechanics and Relativistic Insights. Preprints. https://doi.org/10.20944/preprints202405.0706.v1

4. Dark energy and the structure of the Coma cluster of galaxies. A. D.  Chernin, G. S.  Bisnovatyi-Kogan, P.  Teerikorpi, M. J.  Valtonen, G. G.  Byrd, M.  Merafina. A&A 553 A101 (2013). DOI: 10.1051/0004-6361/201220781

5. Thakur, S. N. (2024). Photon Interactions with External Gravitational Fields: True Cause of Gravitational Lensing. Preprints. https://doi.org/10.20944/preprints202410.2121.v1

6. Thakur, S. N., & Bhattacharjee, D. (2023). Phase shift and infinitesimal wave energy loss equations. ResearchGate https://doi.org/10.13140/RG.2.2.28013.97763

Summary of Extended Classical Mechanics: Vol-1 (Rev-2,3)

21 November 2024

This paper explores how classical mechanics can be extended to account for modern scientific concepts like dark matter, dark energy, and negative mass. It focuses on how these concepts affect the understanding of mass and gravitational dynamics.

Key Points:

Equivalence Principle Redefined: The traditional equivalence principle (inertial mass = gravitational mass) is re-examined to include dark matter.

• Matter Mass (Mᴍ): This represents the combined mass of normal (baryonic) matter and dark matter.
• Apparent Mass (Mᵃᵖᵖ): This is a negative mass component introduced to account for situations involving motion and strong gravitational fields. It influences the Effective Mass (Mᵉᶠᶠ), which is the sum of matter mass and negative apparent mass.
• Gravitating Mass (Mɢ): This is the total effective mass of a system, incorporating both matter mass and negative apparent mass. It is equivalent to the mechanical effective mass (Mᵉᶠᶠ).
• Dark Energy and Negative Mass: Dark energy is reinterpreted as a negative apparent mass term, influencing gravitational dynamics.

Modifications to Existing Equations:

• Newton's Second Law is modified to include effective mass and effective acceleration.
• Newton's Law of Universal Gravitation is reinterpreted to account for effective mass.

Methodology:

• Reinterpreting existing concepts in light of extended classical mechanics.
• Developing mathematical models to quantify the relationships between different mass components and their impact on gravitational interactions.
• Analysing how the interplay of mass components affects gravitational forces and dynamics.
• Using simulations to test the models and compare with observational data.

Expected Outcomes:

• Refine the understanding of mass dynamics in extended classical mechanics.
• Explore the implications of negative apparent mass for gravitational theories.
• Gain insights into the role of dark energy and its interaction with matter.

Overall, this research proposes an extended framework for classical mechanics that incorporates modern scientific understanding of mass and gravity.

#ExtendedClassicalMechanics

Discussion:Photon’s Trajectory and Energy Exchange in Gravitational Fields.

ResearchGate Discussion Link here.

Dear Mr. Ilya Boldov,

21 November 2024

Thank you for your thoughtful contributions to our discussion regarding the photon’s trajectory and energy exchange in gravitational fields. While I appreciate your perspective, I maintain several key aspects of the discussion framework deserve more focused consideration.

The discussion centres on a nuanced distinction between intrinsic photon energy (E) and gravitational-interaction energy (Eg), which enables the symmetric energy exchange observed as photons traverse gravitational fields. This framework is grounded in established conservation laws, combining classical mechanics, relativity, and quantum principles. The interpretations align with phenomena such as gravitational redshift and lensing, which are well-documented within relativistic physics.

Your initial dismissal of photon-gravitational interactions as "meaningless" appears to overlook this broader framework. It is widely accepted that photon energy, despite lacking rest mass, possesses an energy equivalent that interacts gravitationally, as evidenced by gravitational redshift and lensing. Your statement that space geometry alone dictates photon paths simplifies these complex interactions and neglects the role of energy conservation in relativistic contexts.

Furthermore, your emphasis on discrete spatial elements and particle geometries in reply2 introduces an interesting but tangential concept that does not directly address the discussion's core argument. While discrete space theory may provide insights into particle motion, it remains unclear how it challenges the proposed framework of E and Eg, which preserves energy conservation in gravitational dynamics. I would welcome a more specific counter or clarification on how this framework conflicts with your perspective.

To advance this discussion constructively, I encourage you to engage directly with the following points:

1. The role of photon energy equivalence in gravitational lensing and redshift phenomena, and how your discrete space model accounts for these relativistic effects.

2. The conservation of energy during photon traversal of gravitational fields, including the distinction between E and Eg, and whether your model preserves or contradicts these principles.

I consider this focused exchange will enhance our understanding and contribute meaningfully to the discourse. I look forward to your response and further exploration of these fascinating topics.

Best regards,

Soumendra Nath Thakur