Gravity Emerges as the Acceleration of Energy
Introduction
Theoretical physics stands on the brink of a paradigm shift. For over a century, General Relativity has provided profound insights into gravity and spacetime. Yet, as we delve deeper into the cosmos, its limitations become apparent. This thesis presents a radical departure from Einstein’s framework, proposing that gravity arises not from spacetime curvature but from gradients in the electromagnetic constants ε0 and μ0, driven by energy density. By reinterpreting E=mc2, we suggest that mass underpins gravitational phenomena and that the interaction between energy density and these constants forms the true mechanism of gravity.
In this work, we explore this theory in detail, offering over thirty pages of rigorous analysis and evidence. Our aim is to ignite scholarly dialogue, inspire curiosity, and expand the horizons of modern physics. This journey promises to redefine our fundamental understanding of gravity and reality itself.
Abstract
Charge Admittance (CA) proposes a novel framework for understanding the universe. It posits that space is not a pre-existing entity but rather a dynamic medium generated by the interaction of moving charges. The rate at which this space emerges is determined by the fundamental constants, electric permittivity (ε0) and magnetic permeability (μ0). This framework further suggests a connection between the dynamics of space generation and the nature of gravity, implying that gravity may arise from the interplay between energy flow and the density of energy itself.
What is gravity? Were faced with a perplexing trinity of interpretations:
Galileo — “Gravity is a force that acts on all objects, regardless of their mass.”
Newton — “Every particle attracts every other particle with a force proportional to the product of their masses.”
Einstein — “The curvature of spacetime is directly related to the energy and momentum of matter.”
Charge Admittance redefines gravity: It is the interaction of a charge in a dipole with the composite μ0ε0 fields in its near field, created by energy photons, altering the speed (c) of those charges.
Can gravity be redefined through Charge Admittance? How does this interaction affect photon speed and explain gravitational phenomena?
Concept
Charge Admittance (CA) is not just another theory; it is a working assumption designed to stimulate discussion and invite rigorous scrutiny. CA presents a novel form of duality where invisible energy plays a fundamental role in shaping the visible universe. This invites rigorous scrutiny and debate, aiming to be validated or discredited by experiments and logic.
In the Charge Admittance (CA) framework, gravity is redefined as the interaction of a charge in a dipole with the composite μ0ε0 fields in its near field, created by energy photons, altering the speed (c) of those charges. This novel interpretation shifts our understanding of gravity from a force or curvature to a phenomenon driven by electromagnetic field interactions.
The Underlying Mechanism of Gravity: The CA framework proposes that the gravitational constant is equal regardless of mass because gravity is an emergent property of the interactions between charges and the μ0ε0 fields. This interaction modifies the speed of energy propagation (c), manifesting as gravitational effects. Here are the key components of this concept:
c (Speed of Light): More than just the speed of light, it’s the rate at which electromagnetic (EM) energy propagates.
Charge: The electrical potential or voltage change associated with EM energy.
μ0 and ε0 Fields: Representing the magnetic permeability and electric permittivity of free space, these fields develop gradients as a charge moves through space.
Near Field Interaction: The region where μ0 and ε0 fields influence new energy, determining the gravitational effects observed.
Understanding Energy Dynamics: CA leverages the concept of admittance to elucidate energy flow and its facilitation through various media. This approach highlights how energy transmission is governed by the medium’s properties. Specifically, CA suggests that the density of the ε0μ0 field dictates both the rate at which energy propagates into space and the field’s density itself. The density of the ε0μ0 field is the friction that causes the photon speed to be restricted to the speed of energy. The changes in the speed of light or energy are what we perceive as gravity.
Reimagining Gravity and the Cosmos: CA reimagines gravity as a consequence of energy rather than mass, challenging traditional cosmological theories. This shift suggests space arises from energy concentrations, not singularities, reshaping our cosmological narrative. It invites novel interpretations of cosmic phenomena and exploration into uncharted theoretical territories.
A New View of Gravitational Fields: Imagine a contour map of our solar system showing the Sun, Earth and Moon. Here’s how to interpret it with CA:
Contour Lines: Represent gravity admittance gradients.
Vector Directions: Each contour line’s gravity acceleration vector points perpendicular to it.
Line Spacing: Reflects energy density variations.
Energy Flow: Moves towards lower impedance areas.
Gravitational Acceleration: Points towards higher impedance volumes – i.e., energy appears to slow down near low impedance volumes.
Imagine a contour map of our galaxy. The Black Blob (formerly known as a black hole) sits at the center, with open space extending beyond the galaxy’s edges. The contour lines on this map represent the galactic gradient, drawing closer together as they approach the Black Blob, akin to altitude lines on a traditional contour map. This gradient superimposes on local gravitational fields, indicating regions of varying energy density. As we move toward the more dense energy regions near the Black Blob, the speed of energy accelerates (the speed of gravitational acceleration approaches that of the speed of energy). However, to an observer, this acceleration appears to slow down, manifesting as a redshift.
Revolutionary Insights: CA’s perspective on energy dynamics offers an elegant insight comparable to Maxwell’s equations, demonstrating the reciprocity of charge and magnetic flux. By recognizing the interplay between energy density, speed, gravity, and mass, CA promises to reshape our understanding of gravity and the dynamics of energy, time, and space.
Mathematics
One of the revolutionary aspects of Charge Admittance (CA) is its approach to gravity. Traditional theories view gravity as a curvature of space-time caused by mass, expressed in Einstein’s field equations:
Rμν − (gμνR/2) + Λgμν = (8πG/c4) Tμν
Which resolves multiple variable fields down to a single vector.
In contrast, CA suggests that gravity emerges from the deceleration or acceleration of energy propagation due to the density of the ε0μ0 field. As energy accumulates and interacts within this field, it creates an acceleration—the gravitational effect—that we mistakenly interpret as the attraction between masses. This perspective not only aligns with observed gravitational phenomena but also provides a new way to understand the behavior of energy in extreme conditions, such as near a black hole, redefined in CA as a “dark brownish red blob” where gravitational acceleration approaches the speed of energy.
Combining Einstein E = mc2 and Maxwell c2 = 1/μ0ε0:
E/m = 1/μ0ε0
This equation indicates equivalency at the charge level as the ratio of energy to mass related to the properties of free space. Since energy is conserved, E remains constant. thus mass m can be viewed as related to c2. When E is constant, any change in mass results in a change of μ0ε0. Likewise any change in μ0ε0 results in a change in mass.
CA Gravitational Acceleration Vector: Gv = – dc/ dx
Where: Gv represents the rate of acceleration, dc represents the change in speed of energy, dx represents the change in distance.
Clarifying the Acceleration: To relate this to gravitational phenomena, we can express the gravitational constant (Gv) in terms of these energy dynamics. If we denote the gravitational acceleration by Gv= – dx/d√(ε0μ0) where gravity is defined as distance with respect to the change in the speed of energy. This can be reduced to Gv=dc/dx. This formulation implies that gravitational effects can be directly linked to variations in the propagation speed of energy within the context of Charge Admittance.
Explanation of the Transition: To connect the change in the speed of energy with gravitational acceleration, consider that: The change in the speed of energy (dc) over a distance (dx) reflects an acceleration. In classical mechanics, acceleration is defined as the change in velocity over time. Here, dc serves as a proxy for velocity changes in the energy flow, with dx corresponding to either time or a spatial dimension (or both).
Verification of Correctness: In traditional physics, c2 is a significant term in both energy-mass equivalence and electromagnetism. Here, Gv2 could be interpreted as relating to changes in the energy propagation squared: Gv2= – (dc/dx)2, However, simplifying to: Gv= – dx/dc aligns with the interpretation of gravitational acceleration as a first-order derivative of the energy speed with respect to distance, making it consistent with classical mechanics and the principles of Admittance.
The Reciprocity of Z0 and Energy Concentration: ∂E/∂Y0 = -k*E
Where: Y0 is the admittance of space, E is the concentration of energy, and k is a constant of proportionality.
This equation states that the rate of change of the concentration of energy with respect to the admittance is equal to the negative of the product of the constant of proportionality and the density of energy. There are similarities between the force of gravity and the force produced by the energy speed gradient and are proportionate. This is an important link in not only showing the organizing energy but also in the relationship of that organization.
Conclusion
Charge Admittance provides a comprehensive redefinition of gravity, emphasizing the interaction between charges and the electromagnetic fields in space. This perspective offers profound insights into the nature of gravitational forces, inviting further exploration and validation through experimentation and mathematical scrutiny.