Introduction
Energy, in its electromagnetic (EM) form, stands as the bedrock of the cosmos, pervading every facet of existence from the macroscopic scale of galaxies to the subatomic realm. It acts as the driving force behind the formation and dynamics of celestial bodies, galaxies, and the intricate web of interactions that define the universe.
Composed of magnetic flux and electrical charge, EM energy facilitates the transmission of information across vast distances, uniquely capable of traversing the void of space between reference frames. Its inherent property of action at a distance is attributed to the gradient frame present within each cycle, endowing it with its own frame of reference.
The genesis of electromagnetic energy lies in the acceleration of charges, leading to the generation and propagation of photons through space, carrying converted momentum. This wave mechanism perpetuates a bipolar charge differential in a planar format, radiating through space while encountering local impedance.
The genesis of electromagnetic energy lies in the acceleration of charges, leading to the generation and propagation of photons through space, carrying converted momentum. This wave mechanism perpetuates a bipolar charge differential in a planar format, radiating through space while encountering local impedance.
History
The concept of energy traces its roots to ancient Greek philosophers like Thales and Aristotle, who contemplated the nature of motion and transformation. Thales proposed that water served as the fundamental substance capable of transitioning between various states, while Aristotle introduced notions of potential and kinetic energy, suggesting inherent tendencies for objects to move or change.
During the medieval and Renaissance periods, luminaries such as Leonardo da Vinci explored mechanical principles and the concept of work, laying the groundwork for future developments in understanding energy.
The 18th century ushered in significant advancements with the scientific revolution, where figures like Benjamin Franklin conducted experiments with electricity, contributing to the concept of electrical energy.
Charles-Augustin de Coulomb’s experiments in the late 18th century elucidated the relationship between electrical charges and the forces they exert, paving the way for the understanding of electromagnetism and electrical energy.
In the mid-1800s, Faraday’s discoveries in electromagnetic induction provided insights into the conversion of energy from one form to another, laying the groundwork for practical applications of electricity.
James Clerk Maxwell’s equations in the mid-19th century provided a unified description of electromagnetism, advancing the understanding of electromagnetic energy and paving the way for technological innovations such as radio and telecommunications.
In the early 20th century, Nikola Tesla’s contributions to electrical engineering, particularly in the development of alternating current (AC) power systems, revolutionized the transmission and distribution of electrical energy.
Around the same time, Max Planck’s research on black-body radiation and quantum theory revolutionized the understanding of energy at atomic and subatomic scales, introducing the concept of quantized energy. Planck’s work laid the foundation for quantum mechanics and fundamentally altered our understanding of energy’s nature.
Temperature, as understood by Planck, is considered a form of electromagnetic energy and is often utilized as a measurement tool for energy, with accelerators like the Large Hadron Collider employing heat or calorimetric measurements to discern energy components.
Albert Einstein’s theory of relativity, formulated in the early 20th century, introduced the revolutionary concept of mass-energy equivalence, expressed through the famous equation E=mc^2. This equation demonstrated the profound relationship between mass and energy, fundamentally altering our understanding of energy and matter’s interrelationship.
Overall, the historical journey of energy, from ancient philosophical musings to modern scientific breakthroughs, underscores the continuous evolution of human understanding and the significant contributions of countless thinkers and researchers.
Within the framework of Charge Admittance, energy is conceived as an interconnected component of the dynamic fabric of the universe. Understanding the fundamental nature of energy within this paradigm is essential for elucidating the intricate dynamics of electromagnetic phenomena and cosmic forces.
Noise: Electromagnetic noise represents inherent randomness in the electromagnetic field.
Charge: Charge, as the basic building block of the universe.
Electrons and Elemental Charge: The relationship between the an electron and the anti-charge at the quantum level.
Photons The building blocks of EM energy.
Quantum: Explore concepts such as quantization, quantum fields, and their implications within the framework of energy and impedance.
EC Quantum Link: An explanation of this new energy-time-space paradigm.
Zero-Point Energy: EM energy is postulated to exhibit an average value of zero within a half-quantum, reflecting a zero-point energy level.
Energy Viscosity: Energy Viscosity (ηᵥ) as a framework for understanding energy propagation marks a significant advancement.
Dipoles: The exploration of light and electromagnetic waves as energy dipoles.
Origination: The first Energy dipoles spin their tale.
Polarity: Polarity, a fundamental property of electromagnetic interactions
Spin: Spin introduces a quantum dimension to energy dynamics
Speed of c: The speed of light defines the velocity at which electromagnetic energy propagates through space.
Spectrum: The electromagnetic spectrum encompasses a diverse range of energy forms.
Spreadsheet: Showing the energy spectrum from Planck energy level to light years.
Redshift: Understanding redshift by integrating Charge Admittance principles focusing on the microscopic interactions of energy dipoles.
Waves: Elemental carriers of EM energy, A critical reassessment of electromagnetic (EM) wave propagation.
Wave Collapse: This note presents a pivotal concept in understanding the behavior of waves and energy in extreme conditions.
Duality: Electromagnetic energy exhibits a duality, behaving both as particles (photons) and waves.
Force: The glue that hold structures together.
EM Coupling: Explore the detailed mechanics of electromagnetic energy coupling.
Photoelectric Coupling:Explore the detailed mechanics of near field coupling.
Photon Interaction: Delve into the intricate dynamics between a smaller charge dipole and the near field of a larger, lower-frequency dipole