The Laboratory Experiment to test for Absolute Time

Research Proposal: Investigating the Effect of Absolute Time on Mass-Energy Equivalence and the Universe’s Energy Structure

Courtesy of Gaia Staff

1. Introduction

The concept of Absolute Time and its associated kinetic energy is an underexplored domain in theoretical physics. This proposal aims to test a model where the kinetic energy of Absolute Tme modifies the relationship between energy and mass, leading to slight but detectable deviations from conventional mass-energy equivalence E = mc2. Specifically, it is hypothesized that the energy associated with Absolute Time could influence both the mass-energy relationship and gravitational interactions, offering new insights into the fundamental structure of the universe.

This investigation builds on a novel theory that Absolute Time is a kinetic energy force interacting with space, creating new potential explanations for phenomena such as cosmological expansion, black hole mergers, and high-precision optical energy shifts. The experimental setup focuses on mass-energy measurements, astrophysical observations (including supernovae and gravitational waves), and high-precision optical experiments to detect these subtle energy shifts.

2. Hypothesis

It is proposed that the total energy of a system in a medium is given by:

Thus, E = mc2 had been redefined as E = mct, i.e. not the speed of light squared, but the speed of light x the speed of time. The speed of Absolute Time, i.e. the speed of the kinetic driving universal expansion, is equivalent to the speed of light in a vacuum. It thus unifies both electromagnetic and kinetic energy within a system.

In the fuller version of this theory, I do explain why although the kinetic energy derived from the Big Bang is a constant, the rate of universal expansion has been measured to be increasing:

https://newagephysics.com/did-einstein-mistake-the-time/

This new equation suggests that the energy of a system is not solely determined by the conventional mass-energy equivalence but also by the kinetic energy of Absolute Time, which interacts with the electromagnetic properties of the medium. This predicts slight deviations from Einstein’s E = mc2, particularly in environments with varying refractive indices or in high-energy astrophysical settings.

In a vacuum, therefore, the two equations will yield exactly the same results, but within a medium, the energy of a system should be marginally higher than predicted by E = mc2 owing to the fact that the kinetic energy of Absolute Time will not be affected by the medium.

3. Objectives

The primary objectives of this research are:

To test for deviations from Einstein’s mass-energy equivalence (E = mc2) by analyzing mass-energy conversions in various media.
To investigate the impact of Absolute Time’s kinetic energy on astronomical phenomena such as supernovae, gravitational waves, and cosmological expansion.
To detect small energy shifts in high-index materials (like glass and diamond) using high-precision optical experiments.
To analyze the implications of Absolute Time’s energy contribution in astrophysical contexts, such as black hole mergers and the expansion of the universe (Dark Energy).

If experiments can be devised which can test whether the proposed energy increase is actually realised, then this would be compelling evidence for the existence of Absolute Time.

Relative Time, therefore, would be considered an ‘illusion’ created by the restrictions resulting from the limited speed of information exchange between observers.

The theory of Universal Absolutivity is far more advanced than this brief outline suggests, and includes a complete geometrical model of how Space, Relative Time, and Absolute Time intersect

https://newagephysics.com/did-einstein-mistake-the-time/

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