Exploring the Foundations of Quantum Admittance
This page serves as a gateway to a series of experimental proposals designed to rigorously test the principles underlying the Quantum Admittance framework. Each test link provides a detailed description of the experimental setup, methodology, and the expected outcomes, aimed at validating or refining the concepts proposed within this theory. These experiments are carefully designed to explore the relationship between gravitational phenomena and quantum-scale interactions, focusing on how changes in energy density and space viscosity influence signal propagation.
As we progress in our understanding, new tests will be proposed and linked here, each contributing to a deeper exploration of the foundational aspects of gravity, energy, and quantum interactions. At the end of this page, a summary section titled “Further Ideas to Test Charge Admittance Theory” will offer additional testable hypotheses, guiding future experimental inquiries and advancing the development of this theoretical framework.
Controlled Impedance Interferometry
This experiment, “Controlled Impedance Interferometry,” is designed to measure gravitational redshift using a precise, fixed-position setup with two distinct arms: one horizontal and one vertical. The vertical arm exploits the gravitational gradient by sending a signal through two paths—one through a controlled impedance medium and the other as a wave propagating through a vacuum. By carefully comparing the transmission characteristics of these signals, we aim to isolate and quantify the influence of gravitational acceleration on signal propagation, particularly focusing on how gravitational redshift affects a wave traveling through a vacuum compared to one constrained by controlled impedance. This setup offers a unique opportunity to observe and analyze the differential impact of gravity on energy propagation, providing critical insights into the interaction between gravity and quantum-scale phenomena.
Redshift & Y0 Field Mesurement
This experiment seeks to explore gravitational redshift and variations in Y0 field gradients using the advanced observational capabilities of the James Webb Space Telescope (JWST) in conjunction with atomic clocks. The JWST’s high-precision instruments offer a unique opportunity to observe redshift effects in distant celestial bodies, while synchronized atomic clocks positioned both on Earth and in space allow for precise time measurement comparisons. By analyzing the correlation between these observations and time variations, we aim to uncover the influence of gravitational fields and Y0 field gradients on time dilation and energy propagation.
Splitting of Photons to find Anti-Electrons
This experiment investigates the spontaneous disintegration of photons, a phenomenon that occurs trillions of times per second across the universe yet remains underexplored in formal experimentation. By examining the process of photon splitting, particularly as observed in electromagnetic wave interactions with antennas, we aim to identify and validate the fundamental components of the photon, including potential anti-electrons. This study focuses on how charge pairs within electromagnetic waves are separated into equal energy poles, which are then analyzed through transformers that are sensitive only to flux fields of opposing polarities, providing critical insights into the nature of photon disintegration.
Measurement of Y0 Field Contours
This experiment is dedicated to investigating the variations in Y₀ field contours, including their orientation and polarization, by measuring time discrepancies among atomic clocks placed at strategically different positions. By analyzing these time differences, we aim to map the Y₀ field’s structure and better understand its influence on both temporal and spatial dimensions. This study could provide key insights into how the Y₀ field interacts with other fundamental forces, contributing to our broader understanding of the quantum fabric of space.
Future Directions: Expanding the Testing Horizon
As we continue to explore the Quantum Admittance framework, several additional experimental avenues present themselves:
Atomic Clocks: Recent experiments, such as the altitude-dependent atomic resonance changes observed by JILA in Colorado, provide preliminary evidence supporting the QA theory. Further studies using atomic clocks could measure the effects of gravity on time, particularly in relation to Y₀ field gradients at varying altitudes.
Reflectionless Scattering Modes (RSM): These experiments involve creating controlled impedance chambers to study the interaction between light waves and matter. By observing how light waves scatter and reflect under different conditions, scientists can gain insights into the impedance of space—a key aspect of the QA theory, which posits that energy is a property of space itself.
Transverse Electromagnetic Cells: Utilizing transverse electromagnetic cells to measure the speed of light across different distances where Y₀ field gradients vary could offer another means to test the QA framework. The varying Y₀ field is expected to influence light propagation, providing measurable differences.
Laser Ring Gyros: Laser ring gyros, which are highly sensitive to changes in rotational reference frames, could detect subtle rotations caused by Y₀ field gradients, as predicted by the QA theory.
Interferometry and Gravitational Wave Detectors: By piggybacking on existing equipment, such as interferometers and gravitational wave detectors, researchers can indirectly infer the impedance or gradient of space. Additionally, spacecraft-based experiments could be designed to measure these properties directly in different regions of the universe.
This comprehensive approach to testing the Quantum Admittance framework will not only validate its principles but also pave the way for new discoveries in the field of quantum gravity.