Clarification on Time Distortion and Phase Shifts in Relation to Falling Clocks

09-09-2024

Dear Mr. Robert A. Phillips,

Thank you for your response concerning falling clocks.

However, the focus of our discussion is "Dark Energy as a By-Product of Negative Effective Mass," and a question about falling clocks is not directly relevant to this topic. Addressing your question on falling clocks might not contribute to the core discussion on Dark Energy and its Negative Effective Mass. I would encourage keeping our conversation focused on the specific topic at hand.

Regarding your statement that a falling clock closer to Earth oscillates more slowly than one at a higher position, leading to a reduction in subatomic kinetic energy proportional to the square of the relative clock rate:

Please note that, scientifically, a clock closer to Earth actually oscillates faster, not more slowly, than one at a higher altitude due to the stronger gravitational force at Earth's surface. This results in a more energetic condition, where higher energy corresponds to a higher frequency and therefore a higher oscillation rate, according to Planck's equation, E=hf.

Your statement seems to touch on how a falling mass under Earth's gravitational force undergoes deformation due to strain, which causes corresponding changes in its dimensions, as explained by Hooke's Law. Furthermore, gravitational force affects the internal subatomic and molecular structure of the falling mass, leading to strain and deformation in accordance with force-mass equations in classical mechanics.

Consequently, the oscillation of the atomic clock is affected, leading to distortion in the clock's time readings. My research paper, titled "Relativistic Effects on Phase Shift in Frequencies Invalidate Time Dilation II," provides a comprehensive explanation and solution to this issue. You can access it at this URL: Relativistic Effects on Phase Shift in Frequencies Invalidate Time Dilation II.

This research demonstrates that variations in gravitational forces (G-forces) cause internal particles of matter to interact, resulting in stresses and deformations within the matter. Distortions in wavelength due to phase shifts in relative frequencies directly correspond to time distortions, as described by the relationship λ∝T, where λ represents the wavelength and T the period of oscillation. Relativistic effects, such as differences in speed or gravitational potential, influence the clock's mechanism through phase shifts in frequencies, resulting in increased wavelengths of clock oscillations and subsequent errors in time readings. These phase shifts, linked to an increase in the wavelength of clock oscillations, cause time distortion.

Experiments conducted with piezoelectric crystal oscillators in electronic laboratories have shown that wave distortions correspond to time distortions due to relativistic effects. The time interval T(deg) for a 1° phase shift is inversely proportional to the frequency (f), indicating that a wave corresponds to a time shift.

For example, a 1° phase shift on a 5 MHz wave corresponds to a time shift of 555 picoseconds (ps).

• For a 1° phase shift, T(deg) = T/360. Since T=1/f, we have:
• 1° phase shift = T/360 = (1/f)/360.
• For a wave with a frequency f = 5 MHz, the phase shift (in degrees) can be calculated as:
• T(deg)= (1/5,000,000)/360 = 555 ps = Δt.

Thus, for a 1° phase shift in a wave with a frequency of 5 MHz and a wavelength λ = 59.95 m, the corresponding time shift (or time delay) Δt is approximately 555 ps.

Therefore, as a falling clock approaches the Earth's surface, it reverses the magnitude of its deformation, thereby reversing the magnitude of time distortion. The phase shift in the oscillation frequency can be used to calculate the magnitude of this time distortion using the following formula:

• For a 1° phase shift: T(deg) = (1/f)/360 = Δt or,
• For an x° phase shift: Δtₓ = x(1/360f₀)

For more details, please refer to my research paper, "Phase Shift and Infinitesimal Wave Energy Loss Equations," available at this URL: Phase Shift and Infinitesimal Wave Energy Loss Equations.

Best regards,

Soumendra Nath Thakur

Mechanical and Cosmic Mass Descriptions in Closed Systems:

Soumendra Nath Thakur

ORCiD: 0000-0003-1871-7803

08-09-2024

Abstract:

This study provides a detailed examination of the mechanical and cosmic mass descriptions within closed systems, focusing on the mass dynamics in galactic clusters and the universe under extended classical mechanics. The total gravitating mass (Mɢ) within a galactic cluster is presented as the sum of matter mass (Mᴍ), which includes both dark and baryonic matter, and dark energy effective mass (Mᴅᴇ), a negative mass component representing dark energy’s "antigravity" effects. The study also defines matter mass density (ρᴍ) and dark energy density (ρᴅᴇ) and relates these to the total mass of the universe (Mₜₒₜₐₗ). In the context of extended classical mechanics, the effective mass (Mᵉᶠᶠ) combines apparent mass (Mᵃᵖᵖ) with matter mass to describe the gravitational dynamics within a system. This formulation, Mɢ = Mᵉᶠᶠ, allows for the integration of apparent mass and dark energy effects, demonstrating how these components influence the gravitational behaviour in closed systems.

Keywords: Galactic Clusters, Dark Energy, Effective Mass, Matter Mass Density, Gravitational Dynamics

1. Total Mass within Galactic Cluster:

Mɢ = Mᴍ + Mᴅᴇ

• Matter Mass (Mᴍ): Represents the total mass of both dark matter and baryonic matter within a specified radius of the galactic cluster.

• Dark Energy Effective Mass (Mᴅᴇ): Defined as a negative mass component arising from the gravitational effects of dark energy. It accounts for dark energy's contribution as a uniform background, resulting in an "antigravity" effect.

• Gravitating Mass (Mɢ): The total effective mass determining the gravitational dynamics of the cluster, combining matter mass and dark energy effective mass.

2. Matter Mass Density within Galactic Cluster:

The density of matter mass (ρᴍ) within the Coma Cluster is given by:

ρᴍ = Mₜₒₜₐₗ/V 

where Mₜₒₜₐₗ is the total mass of matter, and V is the volume of the cluster.

3. Effective Mass Density of Dark Energy within Galactic Cluster:

The density of dark energy (ρᴅᴇ) in the universe is:

ρᴅᴇ = Eᴅᴇ/V 

where Eᴅᴇ represents the total energy of dark energy, and V is the volume. In cosmological models, ρᴅᴇ is often uniform and related to the cosmological constant (Λ).

4. Total Mass of the Universe:

The total mass of the universe combines matter mass and dark energy effective mass:

Mₜₒₜₐₗ = Mᴍ + Mᴅᴇ

5. Total Mass within a System in Extended Classical Mechanics:

The effective mass of dark energy (Mᴅᴇ) is always negative and is greater in magnitude than the combined matter mass (Mᴍ):

Mᴅᴇ > Mᴍ

• Mechanical Effective Matter Mass (Mᵉᶠᶠ): 

This can be positive or negative, depending on the relative magnitudes of matter mass and apparent mass. The effective mass is the difference between matter mass and apparent mass (Mᵃᵖᵖ):

Mᵉᶠᶠ = Mᴍ + (−Mᵃᵖᵖ)

where Mᵃᵖᵖ is always negative.

Mechanical Effective Mass Characteristics:

• Positive when  Mᴍ>∣Mᵃᵖᵖ∣ 

• Negative when Mᴍ<∣Mᵃᵖᵖ∣

Mass Equation in Extended Classical Mechanics:

Mɢ = Mᵉᶠᶠ 

• Matter Mass (Mᴍ): Represents the total mass of both dark matter and baryonic matter within a system.

• Apparent Mass (Mᵃᵖᵖ): Defined as a negative mass component arising from gravitational effects and the motion of mass within the system. It reflects the contribution of the mass in motion as a negative value affecting the effective mass.

• Gravitating Mass (Mɢ): The total effective mass determining the gravitational dynamics of the system. It is equivalent to the mechanical effective mass (Mᵉᶠᶠ).

• Effective Mass (Mᵉᶠᶠ): Defined as a mass component that combines the effects of apparent mass and matter mass. It accounts for the system’s gravitational dynamics, incorporating the "antigravity" effect that occurs when apparent mass exceeds the magnitude of matter mass.

This formulation describes the total gravitating mass (Mɢ) as equivalent to the mechanical effective mass (Mᵉᶠᶠ). The effective mass (Mᵉᶠᶠ) reflects the combined effects of apparent mass and matter mass within the system. The apparent mass is a negative component that influences the effective mass, creating an "antigravity" effect when it exceeds the matter mass.

List of Terms:

• Eᴅᴇ: Total Energy of Dark Energy — The total energy associated with dark energy within a given volume.

• Mᵃᵖᵖ: Apparent Mass — The mass component associated with negative values that affects the effective mass calculation.

• Mᴅᴇ: Dark Energy Effective Mass — The negative mass component resulting from dark energy’s gravitational effects.

• Mᴍ: Matter Mass — The total mass of matter, including dark matter and baryonic matter, within a specified volume.

• Mᵉᶠᶠ: Mechanical Effective Matter Mass — The effective mass that can be positive or negative, derived from the difference between matter mass and apparent mass.

• Mɢ: Gravitating Mass — The total effective mass determining gravitational dynamics within the system.

• ρᴅᴇ: Dark Energy Density — Density of dark energy in the universe.

• ρᴍ: Matter Mass Density — Density of matter mass within a given volume of the cluster.

#GalacticClusters, #DarkEnergy, #Mechanical #EffectiveMass, #MatterMass #MassDensity, #GravitatingMass,

Universal Mass and Dark Energy: Understanding Cosmic Phenomena

08-09-2024

Soumendra Nath Thakur

Exploring the effects of dark energy and universal mass is essential for understanding fundamental cosmic phenomena like the Big Bang. Even though dark energy and the Big Bang singularity can be abstract and less understood, their influence on the universe’s dynamics is observable and significant. By studying these effects, we can gain valuable insights into the early universe and its evolution. Our approach to examining the universal content and gravitational dynamics aligns well with a broader scientific method, integrating observations and theoretical models to build a more comprehensive understanding of cosmic phenomena.

#UniversalMass #DarkEnergy #CosmicPhenomena

Beyond General Relativity: Photon Symmetry in Gravitational Fields and the Universe

ResearchGate Discussion Link

Soumendra Nath Thakur

ORCiD: 0000-0003-1871-7803

07-09-2024

This mathematical presentation explores the behaviour of photons in strong gravitational fields, revealing a symmetrical relationship between photon energy changes and gravitational fields. The equations:

E = hf; ρ = h/λ; ℓₚ/tₚ (Equation 1)

Eg = E + ΔE = E − ΔE; E = Eg (Equation 2)

Eg = E + Δρ = E − Δρ = E; h/Δλ = h/−Δλ (Equation 3)

Eg = E; Δρ =−Δρ; ℓₚ/tₚ (Equation 4)

demonstrate the consistency of photon energy in gravitational fields, highlighting the symmetrical effects of wavelength changes due to gravity. This symmetry contradicts general relativity's predictions, suggesting that the theory might be incomplete or incorrect in this context. By engaging with alternative perspectives and addressing the contradictions raised by these equations, we can foster a deeper understanding of the universe and its underlying laws, ultimately working towards a more complete and accurate description of reality.

The pursuit of knowledge in science is exemplified by valid and established lines of inquiry that challenge the concept of curvature in general relativity. This ongoing refinement of our understanding of the universe is a testament to the dynamic nature of scientific inquiry. Researchers and theorists have proposed alternative perspectives on spacetime, gravity, and reality, aiming to address general relativity's limitations and inconsistencies.

The observed symmetry, where photons gain energy approaching a gravitational well and lose energy leaving it, may hold the key to refining our understanding of spacetime and gravity. This phenomenon, described by the equations Eg = E + ΔE = E - ΔE (Equation 2) and h/Δλ = h/-Δλ (Equation 3), contradicts general relativity's predictions and aligns with other scientific disciplines and mathematical frameworks.

This discrepancy suggests that general relativity might be incomplete or incorrect in this context, warranting further exploration and refinement. Alternative theories, such as quantum gravity and flat spacetime theories, may offer a more comprehensive explanation for this phenomenon. By engaging with these diverse perspectives and addressing the contradictions raised by the equations, we can foster a deeper understanding of the universe and its underlying laws, ultimately working towards a more complete and accurate description of reality.

#GeneralRelativity #PhotonSymmetry #GravitationalFields #QuantumGravity #Cosmology

Energy Dynamics of the Universe: Negative Apparent Mass, Matter Mass, and the Negative Effective Mass of Dark Energy

The First Part

Soumendra Nath Thakur

ORCiD: 0000-0003-1871-7803

07-09-2024

This study title suggests a comprehensive investigation of how various types of mass and energy, including mechanical energy as interpreted in classical mechanics, interact and shape the universe's evolution and expansion.

Energy Dynamics of the Universe: This section explores how dark energy, regarded as potential energy, was the sole energetic form in the primordial universe and later regenerated through motion and gravitational dynamics following the formation of matter mass. The study includes an analysis of the motion and gravitational dynamics of mechanical energy in the context of classical mechanics. It proposes an exploration of how potential energy, kinetic energy, and more exotic forms—such as dark energy (as a form of potential energy)—interact and contribute to the universe's evolution.

Negative Apparent Mass: This term describes a theoretical concept where generated mass appears negative under specific conditions, particularly from a mechanical perspective that involves motion and gravitational dynamics within classical mechanics. This concept is vital for understanding non-intuitive gravitational effects and how such mass influences the universe's structure and expansion.

Matter Mass: This includes both baryonic matter (ordinary matter composed of protons, neutrons, and electrons) and dark matter, which is non-luminous and interacts primarily through gravity. These two forms of matter represent the majority of mass in the universe and are essential in understanding the formation and evolution of cosmic structures such as galaxies, clusters, and filaments.

Negative Effective Mass of Dark Energy: Dark energy is observed to cause the accelerated expansion of the universe, highlighting its crucial role in cosmic evolution. The term "negative effective mass" implies a framework where dark energy possesses properties that effectively counteract gravitational attraction, resulting in a repulsive effect that accelerates the universe's expansion.

Background:

The intercontinental research study, Dark Energy and the Structure of the Coma Cluster of Galaxies by A. D. Chernin et al., introduces three types of mass that are pivotal to understanding the dynamics of the cluster:

Matter Mass (Mᴍ): This represents the total mass of both dark matter and baryonic matter within the Coma Cluster, contributing to its gravitational binding.

Dark Energy Effective Mass (Mᴅᴇ): A conceptual mass that represents the effect of dark energy, characterized by negative pressure, resulting in a negative mass (Mᴅᴇ < 0) that counteracts gravitational attraction.

Gravitating Mass (Mɢ): The net mass responsible for gravitational attraction, combining the effects of matter mass and dark energy, as expressed in the equation:

Mɢ = Mᴍ + Mᴅᴇ

The total mass per unit volume, including both dark and baryonic matter, represents the density of matter mass (ρᴍ) within the Coma Cluster, which is expressed by the formula:

ρᴍ = Mₜₒₜₐₗ/V

​Our earlier research concluded that dark energy and negative apparent mass can be understood as consequences of gravitational dynamics and motion. This framework extends classical mechanics to provide a consistent and coherent explanation for gravitational interactions, accounting for phenomena associated with dark energy.

Additionally, our studies on the evolution and impact of dark energy in the universe have characterized dark energy as the potential energy of the universe, associated with a negative mass (<0). Initially, this negative mass was the driving force behind cosmic inflation and the formation of positive mass. Following this period of rapid expansion, dark energy entered a phase of hibernation as the density of gravitational mass began to exceed that of dark energy.

As the universe continued to evolve, gravitationally bound galaxies formed from regions of denser gaseous mass, leading to a reduction in the average density of this mass. The subsequent scattering of galaxies altered the motion and gravitational dynamics, allowing dark energy to regain influence in the spaces between galaxies and galactic clusters.

Currently, dark energy has reasserted its dominance in intergalactic space. The ongoing interplay between cosmic motion and gravitational dynamics enhances the effects of dark energy, resulting in the accelerated recession of gravitationally bound galaxies.

In the following sections, we will build upon our earlier conclusions that the negative effective mass of dark energy, considered as potential energy, was the sole energetic form in the primordial universe but later regenerated after a period of hibernation following the formation of matter mass. We will then link and interpret the potential energies associated with negative apparent mass and the regenerated negative effective mass of dark energy, post-hibernation, as consequences of gravitational dynamics and motion. These ideas will be discussed within the broader context of the energy dynamics of the universe, specifically focusing on Negative Apparent Mass, Matter Mass, and the Negative Effective Mass of Dark Energy.

Presentations: Analytical Description of Equations

The following equations describe the state of the universe in its primordial phase, specifically before the Big Bang event. Here is an analytical description of each equation:

Primordial Universe Before the Big Bang Event. 

Potential Energy of Negative Effective Mass: Mᴅᴇ <0: Eᴅᴇ,ᴜₙᵢᵥ = ∞ 

• The potential energy associated with the negative effective mass of dark energy, denoted as 

Eᴅᴇ,ᴜₙᵢᵥ, is infinite:

Eᴅᴇ,ᴜₙᵢᵥ = ∞ 

• This signifies that before the Big Bang, dark energy (characterized by a negative effective mass Mᴅᴇ, where Mᴅᴇ <0) dominated the universe with infinite potential energy.

Proportionality of Potential Energy:

• The total potential energy of the universe, (PEᴜₙᵢᵥ) ∝ Eᴅᴇ,ᴜₙᵢᵥ, is directly proportional to Eᴅᴇ,ᴜₙᵢᵥ:

PEᴜₙᵢᵥ ∝ Eᴅᴇ,ᴜₙᵢᵥ, 

• Given that Eᴅᴇ,ᴜₙᵢᵥ =∞, the total potential energy PEᴜₙᵢᵥ is also infinite. This indicates a state where the universe's energy content is entirely determined by the potential energy of dark energy.

Kinetic Energy of the Universe:

• At this stage, the kinetic energy of the universe, KEᴜₙᵢᵥ, is zero:

KEᴜₙᵢᵥ =0

• This implies that there was no movement or expansion happening in the primordial universe, reflecting a static state dominated solely by potential energy.

Total Energy of the Universe:

• The total energy of the universe, Eₜₒₜₐₗ,ᴜₙᵢᵥ, is composed of both potential and kinetic energy:

Eₜₒₜₐₗ,ᴜₙᵢᵥ = PEᴜₙᵢᵥ + KEᴜₙᵢᵥ = ∞ + 0 = ∞

• This reinforces the idea that the universe, in its initial state, was completely governed by the infinite potential energy of dark energy, with no kinetic contribution.

Total Mass Equivalent of the Universe:

• The total mass of the universe, Mₜₒₜₐₗ,ᴜₙᵢᵥ, is described as the sum of effective mass and matter mass:

Mₜₒₜₐₗ,ᴜₙᵢᵥ = Mᵉᶠᶠ,ᴜₙᵢᵥ + Mᴍ,ᴜₙᵢᵥ

where Mᵉᶠᶠ,ᴜₙᵢᵥ = ∞, Mᴍ,ᴜₙᵢᵥ = 0 

​

• This suggests that the universe's mass was entirely in the form of effective mass associated with dark energy, with no conventional matter yet formed.

Force Relationship in the Universe:

• The force within the universe is defined by the product of effective mass and its corresponding acceleration:

Fᴜₙᵢᵥ = Mᵉᶠᶠ,ᴜₙᵢᵥ·aᵉᶠᶠ,ᴜₙᵢᵥ 

Given that the effective mass is infinite and the matter mass is zero, the force related to dark energy's effective mass is also infinitely large.

• This infinite force would have been a driving factor in the subsequent dynamics of the universe's expansion.

Gravitational Force Relationship:

• While the gravitational force relationship is not fully defined in the presentation, it would logically be influenced by the infinitely large effective mass, indicating a dominant repulsive or expansive force in the primordial state.

Interpretation

In the primordial universe, before the Big Bang event, the cosmos existed in a state of infinite potential energy, completely dominated by dark energy's negative effective mass. This negative effective mass carried an infinite amount of potential energy, which was the only form of energy present, as there was no kinetic energy due to the absence of movement or expansion. The total energy of the universe was thus entirely governed by this boundless potential.

During this period, the universe had no conventional matter; its total mass consisted solely of the infinite effective mass associated with dark energy. This situation created an infinitely large force within the universe, stemming from the interaction of dark energy's effective mass with gravitational dynamics. The overwhelming presence of this force and energy likely set the stage for the subsequent expansion and evolution of the universe, ultimately leading to the Big Bang and the formation of matter as we know it.

Post-Big Bang Event

Potential Energy After the Big Bang:

• The potential energy of the universe, PEᴜₙᵢᵥ →0, approaches zero after the Big Bang event:

 PEᴜₙᵢᵥ →0

• This indicates that, following the Big Bang, the potential energy previously associated with dark energy's negative effective mass has diminished to negligible levels.

Kinetic Energy After the Big Bang:

• The kinetic energy of the universe, KEᴜₙᵢᵥ, becomes infinite:

KEᴜₙᵢᵥ = ∞

• This suggests that immediately after the Big Bang, the universe underwent rapid expansion, resulting in infinite kinetic energy due to the dynamic motion of matter and radiation.

Total Energy of the Universe:

• The total energy of the universe, Eₜₒₜₐₗᴜₙᵢᵥ, is the sum of potential and kinetic energy:

Eₜₒₜₐₗ,ᴜₙᵢᵥ = PEᴜₙᵢᵥ + KEᴜₙᵢᵥ = 0 +  ∞ =  ∞

• This reflects that, in the aftermath of the Big Bang, the universe’s total energy is dominated by the infinite kinetic energy, as the potential energy has become negligible.

Total Mass Equivalent of the Universe:

• The total mass of the universe, Mₜₒₜₐₗ,ᴜₙᵢᵥ, is now described solely by the matter mass:

Mₜₒₜₐₗ,ᴜₙᵢᵥ = Mᴍ

where Mᴍ represents the conventional mass of baryonic and dark matter formed after the Big Bang.

• This indicates that, after the Big Bang, the universe's total mass is comprised of matter mass, with the previous effective mass associated with dark energy no longer contributing to the mass.

Force Relationship in the Universe:

• The force within the universe can be related to the total mass and its acceleration:

Fᴜₙᵢᵥ = (Mᴍ,ᴜₙᵢᵥ + Mᵉᶠᶠ,ᴜₙᵢᵥ)·aᵉᶠᶠ,ᴜₙᵢᵥ 

Given that the matter mass Mᴍ,ᴜₙᵢᵥ is non-zero (>0) and the kinetic energy is infinite KEᴜₙᵢᵥ = ∞, the forces involved in the universe’s expansion and structure are influenced by this mass and the accelerating expansion.

Gravitational Force Relationship:

Although not fully detailed, the gravitational forces in the universe after the Big Bang would be influenced by the distribution of matter mass and the resulting gravitational dynamics, moving away from the previously dominant repulsive forces of dark energy.

Interpretation

Following the Big Bang, the universe transitioned from a primordial state of infinite potential energy to one characterized by infinite kinetic energy. This shift marks the onset of rapid expansion, where the potential energy associated with dark energy's negative effective mass became negligible, and kinetic energy surged to dominate the universe’s energy composition.

During this phase, the total energy of the universe is described by the infinite kinetic energy resulting from the initial expansion. The mass of the universe is now composed entirely of conventional matter, reflecting the formation and distribution of baryonic and dark matter in the aftermath of the Big Bang. The forces driving the universe’s evolution are now governed by this matter mass and the dynamic motion, leading to the ongoing expansion and structuring of the cosmos.

To be continued ...

#EnergyDynamicsOfUniverse, #NegativeApparentMass, #MatterMass, #NegativeEffectiveMass #DarkEnergy,