Quantum Admittance

Abstract

Quantum Admittance represents a groundbreaking paradigm shift, akin to the revolutionary discoveries of Relativity and the Higgs mechanism. It encapsulates the essence of the universe by defining space as a passive void, only realized as a dynamic medium when endowed with energy. The rate at which this occurs is characterized by the density of electric permittivity (ε0) and magnetic permeability (μ0). This dynamic lattice serves as the foundation upon which the intricate tapestry of the time-energy-space universe is woven by the natural vortex of a never-ending fractal.

Introduction

By investigating the intricate interplay between quantum vortices and galactic formations, we aim to unveil the underlying dynamics shaping the cosmos, from subatomic particles to the vast expanses of the universe. Through this holistic perspective, we endeavor to illuminate the interconnectedness of phenomena across scales and deepen our comprehension of the universe’s grand tapestry.

Gravity, an invisible “hand” shaping the cosmos, has intrigued humanity for centuries. From the moon shaping the tides to the dance of galaxies around black holes, gravity orchestrates the universe’s symphony. Expanding on the concept of vortices across different scales, we delve into self-similarity and fractal geometry. Just as fractals exhibit self-repeating patterns at various scales, vortices—from the quantum realm to cosmic dimensions—may manifest similar characteristics. This self-similarity suggests a fundamental organizing principle underlying the universe’s structure, where patterns emerge from the interactions of energy and spacetime.

This thesis explores Quantum Admittance (QA), proposing gravity as an outcome of energy flow through time, bridging General Relativity and quantum mechanics. QA’s simplicity offers a novel perspective on gravity, potentially revolutionizing our understanding of fundamental forces.

The Question

What is gravity?

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.”

Were faced with a perplexing trinity of interpretations:

QA Answer — “Gravity is the acceleration of energy due to increasing density compressing ε₀μ₀ fields.”

Insights

Energy Dynamics: QA emphasizes energy flow over particles or mass, focusing on the movement of energy and its effects on the universe.

Admittance over Impedance: QA uses the concept of admittance to better explain how energy dynamics operate, highlighting the importance of energy flow.

Energy Travel in a Vacuum: In QA, energy moves through a self-generating lattice in the ε₀μ₀ field, providing a modern twist on the old Aether concept.

Gravity as Energy Acceleration: QA interprets gravity as the result of energy acceleration, offering a novel way to understand gravitational phenomena.

Postulates

Energy Flow as a Driving Force: QA posits that energy flow, rather than mass, is the primary force behind gravity.

Rate of Energy Flow: Changes in the rate of energy flow create accelerations that we interpret as gravity.

Dual-Component Gravity: QA proposes both instantaneous and delayed components to gravity, explaining gravitational aberrations attributed to gravity waves. This dual-component view aligns with current theoretical physics and offers insights into gravitational interactions over cosmic scales.

QA Concept

Quantum Admittance and Energy Flow: How about this: Quantum Admittance and Energy Flow: Quantum Admittance examines the dynamic interaction between time and energy. It proposes that the density of the ε0μ0 field governs both the rate at which energy flows into space and the density of the field itself.

The recognition of the reciprocity between energy density and energy speed, akin to Maxwell’s groundbreaking equations, underscores the depth and complexity of Quantum Admittance theory. Just as Maxwell’s equations revolutionized our understanding of electromagnetism, this insight into the relationship between energy density and speed promises to reshape our comprehension of gravity and energy-time-space dynamics.

Mathematics

The Rate at Which Energy is Accepted by Time: Y₀=√(ε₀/μ₀)

Where: Y₀ represents the Admittance of a Field to a Change in Energy Density, ε₀​ represents Permittivity, and μ₀ represents Permeability.

This equation reveals the rate at which energy is admitted into the electromagnetic (EM) field. This equation unveils the dynamic interplay between energy and the EM field. It offers insights into how time accommodates and interacts with energy concentrations, shaping the gravitational phenomena we observe.

The Equivalence of Mass and Energy: E=mc²

Where: E represents energy, m represents mass, and c represents the speed of light in a vacuum.

Einsteins famous equation formalizing the theory of Relativity. This equation shows energy and mass are equivalent and interchangeable. A foundational element of Quantum Admittance.

Rearranging the equation: E/m = c²

Maxwell’s equation for the speed of energy: c² = 1/μ₀ε₀

Where: c² represents the speed of energy squared, ε₀​ represents Permittivity, and μ₀ represents Permeability.

Combining Einstein and Maxwell: E/m = 1/μ₀ε₀

This equation indicates that the ratio of energy to mass is directly related to the properties of free space, specifically its permittivity and permeability.

Interpreting the Combined Equation: Since energy is conserved, E remains constant. Thus, the mass m can be viewed as inversely related to c2, indicating that gravitational effects can be understood in terms of changes in the speed of light or energy propagation.

Gravitational Acceleration Vector: G_v​ = d_c/ d_x

Where: G_v represents the rate of acceleration, d_c represents the change in speed of energy, d_x represents the change in distance.

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). Note the difference between GR which chooses time and QA which chooses distance. That is: GR changes the speed of “Time” and QA changes the speed of “energy” as the underlying mechanism that causes gravitational acceleration.

Clarifying the Acceleration: To relate this to gravitational phenomena, we can express the gravitational constant (G_v) in terms of these energy dynamics. If we denote the gravitational acceleration by G_v​= d_x/d_{√(ε0​μ0)} where gravity is defined as distance with respect to the change in the speed of energy. This can be reduced to G_v​=d_c/d_x​. This formulation implies that gravitational effects can be directly linked to variations in the propagation speed of energy within the context of Quantum Admittance.

Verification of Correctness: In traditional physics, c² is a significant term in both energy-mass equivalence and electromagnetism. Here, G_v²​ could be interpreted as relating to changes in the energy propagation squared: G_v²=(d_c/d_x)², However, simplifying to: G_v​=d_x/d_c 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 Quantum Admittance.

Coupling to the Mechanism: The Quantum Lattice

Referencing E/m = 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.

The next link to the concept of gravity being linked to the properties of the Quantum Lattice is the relation of the parameters ε₀μ₀ to the “Admittance” space, Y₀, as shown above. This is the ability to accept energy in time, and is foundational to the remainder of this project.

The Reciprocity of Z₀ and Energy Concentration: ∂_E/∂Y₀ = -k*E

Where: Y₀ is the impedance of space, E is the concentration of energy, and k is a constant of proportionality.

This elegant insight is as important as Maxwell’s 4th equation, which shows the reciprocity of charge and magnetic flux.

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 based on its quantum nature.

Visualization

The Lattice: In Quantum Admittance (QA), the universe is depicted as a dynamic, multi-dimensional lattice structure, where time serves as the fourth dimension, introducing a fundamental aspect of temporal evolution and interaction. This lattice evolves through the resonance and interplay of energy at various levels, providing a comprehensive framework to understand gravitational phenomena and other forces in the cosmos.

5D Fractal: Imagine a structure where each point represents an energy state. This mesh lattice is not static; it evolves over time, twisting and resonating at different levels. The interactions within this matrix define the gravitational landscape, replacing the simpler visualization of a ball distorting a trampoline. Instead, gravity is seen as the result of intricate energy flows within this multi-dimensional framework.

Key Concepts:

3D Physical: The three spatial dimensions is made of a ε₀μ₀ lattice. Each dimension of the lattice corresponds to a specific spatial direction, facilitating a deeper understanding of the intricate energy patterns that permeate the universe.

4D Time: Time serves as the fourth dimension within QA’s framework, introducing a fundamental aspect of temporal evolution and interaction. This temporal dimension allows for the dynamic representation of energy propagation over time, capturing the evolving nature of cosmic phenomena.

5D Interaction: In addition to the spatial dimensions and time, QA incorporates a fifth dimension to represent the twist in the energy lattice. This twist reflects the dynamic evolution and interaction of energy structures over time, providing a comprehensive framework to explore the complex dynamics of the universe. This dimension offers a detailed representation of how energy propagates and interacts within the cosmos.

Resonant Levels: Energy lattices resonate at various levels, creating a multi-scale framework where each level influences and is influenced by others. These resonances help explain phenomena at both quantum and cosmic scales.

Dynamic Interactions: Energy lattices grow, twist, and interact, forming complex patterns that account for gravitational effects and other fundamental forces. This dynamic nature captures the constant flux and evolution of the universe.

Lattice Boundaries: At the boundaries where different energy lattices meet, interactions can create friction and complex tilts, resulting in phenomena like frame dragging and Lagrange vortices.

Emergence

1. The Planck scale energy dipole emerges as the basic form of energy.

2. Energy density controls the viscosity of the ε₀/μ₀ field.

3. Changes in viscosity affect the speed of energy propagation.

4. Time facilitates the movement of energy according to QA viscosity contours..

5. Propagating energy creates disturbances, akin to ripples in a pond.

6. These disturbances form a lattice based on their origin, speed and intervening QA viscosity contours.

7. When energy encounters changes in admittance, it deflects.

8. Deflections cause energy sidebands. Energy lost to sidebands is seen as redshift

Implications

Black Holes: With QA, black holes represent extremely dense energy concentrations where light is slowed by an extremely dense μ0ε0 field. However, it can never be so dense as to stop the flow of energy, because it is the flow of energy that builds the field. The speed of energy is asymptotic to zero but never zero. 

Big Bang: QA offers insights into how matter and energy come together to form structures in the universe, precluding the need for the Big Bang. The fact that the universe did not start from a singularity also solves the varying rate of expansion claimed to be part of the early universe’s expansion rate profile. With the “gathering capability” of QA, there is no need for a Big Bang to start the universe from a singularity. Instead, there may be evidence of events that appear as vestiges of the reverse, the big “whoosh.”

Expansion: The fact that the universe did not need to start from a singularity solves the enigma of a varying rate of expansion claimed to be part of the early universe’s profile. What is seen is variation in the rate of expansion of individual galaxies within the structure of the cosmos. Using these profiles as individual snap shots of time offers a better insight than making case they should be to make a case for a Bang that was never heard, as without the Big Bang, the need for expansion to explain the size and redshift in no longer required.

Redshift: Redshift is not a stretching of time per se, but a reduction in amplitude manifesting as a longer wavelength. This effect resembles the stretching of the recorded travel path of light through space as it navigates varying energy fields.

Time Dilation: In QA, time dilation is addressed by considering the impedance of space and its variations along different paths to observers from the charge movement or “energy event” that initiates the wave. Observers at the same distance but in different directions may experience different time delays due to impedance differences. Gravitational lensing on each path can lead to varying redshifts observed by different observers. This perspective offers insights into temporal distortions caused by varying space properties, with implications for testing QA’s predictions. This concept is analogous to using coax phasing lines to adjust signal phasing or delays in phased array antennas or precision test equipment.

Ultraviolet Catastrophe: QA Theory averts the Ultraviolet Catastrophe by recognizing that the wavelength of electromagnetic radiation corresponds to the magnetic field size during one dipole spin at the Planck scale. As the spin rate exceeds the dipole length, dissociating from dipole size, the energy density limit is reached. This understanding of photon behavior at the quantum scale offers a solution, highlighting the need to revise traditional models for quantum phenomena.

Unification of forces: QA Theory posits that electromagnetic forces and gravitational forces are two sides of the same coin. Electromagnetic forces organize energy fields, creating gradients that facilitate energy acceleration, forming the basis of gravity. The interplay of near-field and far-field configurations of magnetic flux couplings provides an understanding of these forces. The strong nuclear force dominates in the near field but weakens where the magnetic flux opens. Exploring these interconnections and unifying principles may reveal new insights into the fundamental fabric of energy and particles.

Predictions

Quantum Admittance provides insights into various cosmic phenomena, challenging conventional notions and offering a unified understanding of fundamental forces:

Age of the universe: With the constant processing of energy to maintain equilibrium, the universe may function as an ongoing mechanism, defying a measure of its beginning.

Size of Universe: Without a time limit on the universe’s age, there is no limit to its size. The universe is not bound by a predetermined size

Quantization of Gravity: QA addresses the quantization of gravity by recognizing that the impedance of space, governing the speed of weightless photons, is fundamental. Gravity is connected to photon energy through the μ₀ε₀ fields, aligning with Planck’s constant. This understanding forms the basis for gravity quantization. Additionally, considering mass quantization and the relationship expressed by Einstein’s equation E=mc², it follows that energy must also be quantized.

Proof

Quantum Admittance withstands scrutiny against General Relativity’s established proofs: This demonstrates its validity within its own theoretical framework. QA acknowledges that General Relativity has provided valid proofs within the framework of its own principles. However, it introduces a novel perspective by suggesting that the observed phenomena traditionally attributed to space-time warping could also arise from changes in the speed of energy within the Quantum Admittance framework.

Pound-Rebka experiment: Important clues about the various interpretations that can be gleaned are either the speed of energy is changed or the time between the points where it is measured must be changed to show the difference in the frequency of energy observed. It is noted that the difference in frequency of energy is EXACTLY that a change in the speed of energy would manifest. It appears the as if the speed of light is changed according to that of a massif it were dropped or launched along the same path. Under relativity, the observed “blueshift” in energy is attributed to a change in time. The clocks at the top and bottom run at different frequencies. Originally designed to test relativity, the experimenters concluded that this proof was inconclusive for that case.

Under QA, the observed “blueshift” in energy is attributed to a change in the speed of energy. The wavelength is stretched by gravity. There is strong proof that one or the other is correct. The different interpretations have not been proved let alone tested. That is a goal of this project.

ZILA Experiments: Recent experiments by ZILA show that energy is exactly accelerated at the speed of gravitational attraction with extreme accuracy with single electron oscillation periods differing at individual elevations within adjacent atoms. These are the equivalent of accurate version of the Pound-Rebka Experiment carried out at the atomic level,

Alignment with Astronomical Observations: QA seeks validation through alignment with recent observations from telescopes like James Webb, potentially revealing new insights into the behavior of gravity at large scales.

Concordance with Existing Experiments: Predictions made by QA are compared with established experimental results, such as gravitational wave detection by LIGO. This comparison helps asses the theory’s potential to explain the two speeds of gravity phenomena, the field and the refresh of the field by the changing energy concentrations.

Experiments

Dual Plane Interferometry

Description: This experiment aims to measure gravitational redshift using a fixed position setup with two arms: horizontal and vertical. By comparing signal transmission through different media along these paths, the effects of gravitational acceleration on signal propagation can be assessed

Setup: The experiment utilizes a fixed platform with two arms extending horizontally and vertically from a central point. Energy sources and detectors are positioned at the ends of each arm, ensuring a consistent distance between them throughout the experiment.

Energy Emission: A single signal is emitted simultaneously from the central source by being split into two paths, each using an identical length of coaxial cable, one along the horizontal arm and the other along the vertical arm.

Energy Transmission: At the end of each arm the signal is converted to an EM signal to be propagated back to the central point by an identical method in each path which leaves it propagation open to the ε₀ μ₀ field.

Energy Detection: At the center of each arm, detectors measure the received signals. To ensure accurate measurements, the time taken for energy to traverse each path is precisely referenced using interferometers.

Expected results: The “free space” signal traversing the vertical path shows frequency shift indicating a gravitational redshift or blueshift, depending on the direction of the signal flow, due to changes in gravitational potential energy (as seen by Pound-Rebka). The “free space” signal traversing the horizontal path will exhibit minimal frequency shift, as the impedance remains constant due to the lack of gravitational variations. The control or reference signal traveling in the coaxial cable will be unchanged in either case.

Analysis: By comparing the observed frequency shifts between the horizontal and vertical arms, the impact of gravitational acceleration on signal propagation can be quantified. Any differences in frequency shift between the two paths will provide insights into the gravitational effects on signal transmission through different media.

Conclusion

Quantum Admittance offers a unified framework transcending classical and quantum physics, redefining gravity as the consequence of energy flow through a dynamic medium. By illuminating the interconnectedness of all phenomena, Quantum Admittance invites a reevaluation of our understanding of the universe.

The implications of Quantum Admittance are profound, offering a unified framework that transcends the dichotomy between classical and quantum physics. By redefining gravity as the consequence of energy flow through a dynamic medium, Quantum Admittance unveils a new hierarchy of emergence, wherein the very fabric of space itself shapes the behavior of the cosmos.

Just as DNA contains the genetic code that orchestrates the growth and development of living organisms, ε₀/μ₀ serves as the foundational blueprint for the universe’s energy dipole lattices. Akin to bubbles expanding into the void of space, these initial structures, imbued with the potentiality encoded in ε₀/μ₀, expand and evolve, shaping the ever-expanding dimensions of space. The pressure exerted by the dynamic interplay of ε₀μ₀ within this primordial miasma controls the speed of the continual admission of Quantum Dipoles into the cosmic void.