24 March 2024

RT-1: The Primordial Universe: Concepts in Theoretical Physics and Cosmology

This research text discusses some concepts related to theoretical physics and cosmology, particularly regarding the nature of the universe at its earliest moments. Here's a breakdown and interpretation of the text:

0-th Dimensional State: This state is described as having the highest potential energy, with infinite non-eventful potential energy points that eventually transform into eventful kinetic energy points. These kinetic energy points are posited to be the source of the universe's kinetic energy and signify the beginning of the Big Bang event.

Frequency (f₀): This refers to the frequency of an eventful energy point. In the 0-th dimensional state, the frequency is denoted as f₀, with the assumption that x Hz is greater than fₚₗₐₙₖ, which represents the Planck frequency.

Time (t₀): This represents the beginning time of the eventful energy points in the 0-th dimensional state.

Planck Time (tP): This is the time required for an eventful energy point to reach the photon frequency f₀ at the Planck scale, which is denoted as tP = 5.39 × 10⁻⁴⁴ s.

Planck Frequency (fₚₗₐₙₖ): This is the frequency associated with the Planck scale, denoted as fₚₗₐₙₖ = 1.855 × 10⁴³ Hz. It's described as c³/h, where c is the speed of light (299792458 m/s) and h is the Planck constant (6.62606868 × 10⁻³⁴ J·s).

This text outlining a conceptual framework for the early stages of the universe's development, drawing from theories such as quantum mechanics and cosmology. It introduces ideas related to energy states, frequencies, and time scales at the very beginning of the universe's existence, particularly emphasizing the transition from a state of high potential energy to eventful kinetic energy points, which are proposed to initiate the Big Bang event.

23 March 2024

A Massive Phase Shift for the Planck Frequency in Transition to the 0th Dimensional State:

Soumendra Nath Thakur ORCiD: 0000-0003-1871-7803 Dated 23-03-2024

In the realm of quantum mechanics, the transition to higher dimensions often entails profound transformations in the behaviour of fundamental particles. Among these, the photon, a quantum of light, exhibits remarkable changes as it traverses into higher-dimensional states. A particularly striking phenomenon observed during this transition is the occurrence of a massive phase shift in the Planck frequency of the photon. This phase shift, often exceeding thousands of degrees, signifies a significant alteration in the oscillation pattern and quantum properties of the photon. In this discussion, we delve into the implications of such a massive phase shift for the Planck frequency as the photon transitions to the elusive 0th dimensional state. Through this exploration, we aim to unravel the intricate nature of dimensional transitions and their impact on fundamental particles in the quantum realm.

The transition of the photon to the 0th dimensional state entails a notable change in its frequency and phase characteristics. One of the key observations is the occurrence of a massive phase shift for the Planck frequency (fₚₗₐₙₖ) of the photon. Let's denote the magnitude of this phase shift as θ, measured in degrees.

θ = 2482.76°

This significant phase shift suggests a profound transformation in the quantum properties of the photon as it transitions to the 0th dimensional state. Such a deviation from its original phase angle implies an intricate interplay of quantum mechanics and dimensional transitions, shedding light on the complex nature of the quantum realm.


22 March 2024

The accountability for all types of external effects on clock oscillation extends beyond just relativistic effects:

By: Soumendra Nath Thakur. 22 March 2024

It's essential to recognize that various factors beyond relativistic gravity, such as temperature, mechanical forces, motion, and other external influences, can distort stable oscillations. Thus, attributing distortions solely to gravitational effects is overly simplistic.

Addressing these distortions requires a comprehensive approach, involving the calculation of all external influences through correlation according to universal standards. In this regard, Newtonian mechanics offers a more robust framework for understanding the impact of external factors on oscillations compared to the limitations of relativistic gravity theory.

It's worth noting that while relativistic gravity plays a role, particularly in extreme scenarios, its practical impact may be better understood through a Newtonian lens in many cases.

This version emphasizes the importance of considering multiple factors in understanding clock oscillation distortions and highlights the comparative strengths of Newtonian mechanics in addressing these complexities.


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Previous version 2:

The accountability for all types of external effects on clock oscillation extends beyond just relativistic effects:

Not only gravitational effects due to relativity, but also factors such as temperature, mechanical forces, motion, and any other external influences can lead to distortions in stable oscillations. Therefore, claiming that gravitational effects are solely responsible is not accurate; various external influences can cause similar distortions in oscillations.

The proper approach to address these distortions is by calculating all of them through correlation according to universal standards. Newtonian mechanics provides a better framework for accounting for these external impacts compared to the flawed relativistic theory of gravity in spacetime.

It's important to note that relativistic gravity alone cannot adequately address these distortions since gravity behaves more in line with Newtonian mechanics in practical applications."

The hashtags at the end indicate the key topics of the discussion: #externaleffects, #clockoscillation, and #timedistortion.

Previous version 1:

Accountability of all forms of external effects on clock oscillation, not only relativistic effects: Not only relativistic gravity, but also temperature, mechanical forces, motion and any other external influence will cause distortions in stable oscillations, not just gravitational effects.
So your claim of the gravitational effect is not exclusive, but common to other external influences those cause distortions in the oscillations.
Calculating all distortions through correlation according to universal standardization is the only way to address these.
Newtonian mechanics can better account for all such external impact related distortions than the flawed relativistic gravity of spacetime.
Only relativistic gravity does not address these of course, as gravity is not only relativistic but more Newtonian in practical applications.

#externaleffects, #clockoscillation, and #timedistortion.

21 March 2024

Cosmic Dynamics: Galaxies, Black Holes, and the Universal Sea of Anti-Gravitational Disturbance

Soumendra Nath Thakur ORCiD: 0000-0003-1871-7803 Dated 21-03-2024

"Galaxies and clusters of galaxies, similar to black holes and clusters of black holes, are moving outward into space within a universal sea of anti-gravitational disturbance."

This statement paints a vivid picture of a universe in motion, with galaxies and their clusters being influenced by forces beyond just gravity, hinting at the complex interplay of various phenomena in shaping the large-scale structure of the cosmos.


Galaxies and Clusters Drifting Outward: This part suggests a dynamic picture of the universe where galaxies and clusters of galaxies are not static but are in motion. The mention of them "drifting outward" implies an expansionary movement, indicative of the overall expansion of the universe as described by the Big Bang theory.

Similarity to Black Holes: Comparing galaxies and clusters of galaxies to black holes and clusters of black holes implies some commonality in their gravitational interactions. Black holes are known for their intense gravitational pull, suggesting that galaxies and their clusters may have similar effects on the surrounding space.

Universal Sea of Anti-Gravitational Disturbance: This phrase introduces the concept of an "anti-gravitational disturbance," suggesting a force acting counter to gravity. In cosmology, dark energy is often associated with such anti-gravitational effects, driving the accelerated expansion of the universe. The term "universal sea" evokes the idea of a pervasive influence that affects all celestial bodies uniformly.

Tug of war between gravity and dark energy:

The energy from the Big Bang drove the universe's early expansion. Since then, gravity and dark energy have engaged in a cosmic tug of war. 

Gravity pulls galaxies closer together; dark energy pushes them apart. Whether the universe is expanding or contracting depends on which force dominates, gravity or dark energy #gravity #darkenergy

This statement by Soumendra Nath Thakur highlights the ongoing struggle between two fundamental forces in the universe: gravity and dark energy. The analogy of a "tug of war" depicts the dynamic interaction between these forces, which influence the expansion or contraction of the universe. Gravity, a familiar force that attracts matter, tends to pull galaxies closer together. In contrast, dark energy, a mysterious force associated with the acceleration of the universe's expansion, pushes galaxies apart. The outcome of this cosmic tug of war determines the overall fate of the universe, whether it continues to expand indefinitely or eventually contracts. 

The hashtags #gravity and #darkenergy emphasize the significance of these forces in shaping the structure and evolution of the cosmos.