Features

No new particles

In contrast to some other theories, Quantum Acceptance does not require the introduction of new particles to explain observed phenomena. By adhering to the principle of simplicity and Occam’s Razor, this theory maintains a minimalist approach while providing comprehensive explanations for complex cosmic phenomena. This simplicity enhances the elegance and clarity of the model, making it accessible and intuitive to both experts and enthusiasts alike.

No variable constants

Unlike General Relativity, QA does not require the changing of human defined constants into variables to mechanize a theory. QA uses existing and proven foundational physics concepts to explain gravity.

Mechanism for quantification of gravity explained

At the core of QA lies the concept of “equivalent” gravity, stemming from the acceleration of energy. This principle, coupled with Planck’s revelation of energy quantization, establishes a direct correlation between gravitational acceleration and energy quantification. This alignment with Planck’s seminal discoveries provides a unified explanation for observed gravitational phenomena within the framework of QA.

Gravity waves explained

Offering a coherent explanation for gravity waves, QA explains the ripples in energy concentration caused by energy moving. This insight into the dynamics of gravitational waves enhances our understanding of astrophysical phenomena such as black hole mergers, neutron star collisions, and other cataclysmic events.

Redshift explained

QA offers a cogent explanation for redshift phenomena by integrating the concept of entropy, restating the principle of “tired light.” This concept describes the gradual reduction in energy intensity over vast cosmic distances, as each gravitational bending of energy causes it to follow a longer path and undergo stretching.

Compatibility with JWST

The predictions of QA align seamlessly with observations from the James Webb Space Telescope (JWST), demonstrating its compatibility with real-world data. This scalability with cutting-edge observational technology reaffirms the robustness and validity of QA as a framework for understanding the universe’s intricacies.

SEEP (Standard Earth Electromagnetic Parameters)

Similar the concept of “Standard Temperature and Pressure” (STP) in chemistry, QA introduces SEEP, to calibrate relationships of numbers used in calculating QA’s mathematical relationships. By emphasizing the fundamental role of energy exchange, SEEP enhances our understanding of complex astrophysical processes and facilitates the development of more accurate models of cosmic phenomena.