Fields

EM fields are mediums in space that allow for the storage and movement of energy. The near field is where energy is at its origin. The mid-near/far field is where energy is leaving the embryo. The amplitude of these waves results from the sum of all photons in resonance. The far field is where energy is unbound from its source.

EM Fields and Energy

Electromagnetic (EM) fields are fundamental forces that govern the interactions between electrically charged particles. EM fields are created by moving charges, and they propagate through space at the speed of light. EM fields are responsible for a wide range of phenomena, including electricity, magnetism, light, and radio waves.

Energy fields may overlay each other to increase field density with same or different frequencies of energy occupying the same space. Each field may have characteristics which determine the speed of propagation through it. Fields transfer perturbations of electromagnetic energy at the speed of the medium.

There are alleged to be fields associated Fields represent mediums to contain specific characteristics of energy. For Photons (Gauge Boson identified as the electromagnetic energy particle) there are two fields, these are Permittivity and Permeability which allow storage of charge and magnetic flux respectively.each Standard Model Boson. Photons are Bosons.

EM Field and Poles

In the framework of energy fields, the establishment of gradients necessitates the presence of polarity, akin to the poles observed in magnetic fields. These poles serve as the points of reference for the direction and intensity of the gradient, facilitating the organization and flow of energy within the field.

Regions of the EM Field

The EM field can be divided into three regions: the near field, the mid-near/far field, and the far field.

Near Field: The near field encompasses the region where energy originates. Energy transfer within the near field occurs through close coupling between the energy source and the load. The impedance within the near field is complex and can even be negative. It is within the near field that all action, force, and energy interactions take place. Additionally, the near field acts as the local frame of reference for measuring the speed of energy.

Mid-Near/Far Field: The mid-near/far field represents the transitional region where energy is leaving its source. The impedance within this region is complex, and it may encompass one pole of a photon dipole within the near field of another. Interactions in this region involve half-spin behavior, and it is also the domain where entanglement phenomena may occur.

Far Field: The far field is the region where energy becomes unbound from its source. It takes the form of open dipoles, which are free to resonate with other energy photons. These resonant interactions give rise to waves, which are characterized by their frequency or wavelength. The amplitude of these waves results from the sum of all photons in resonance. Information within the far field is instantly accessible at each point, and it travels at the speed of energy. The far field is also known as the wave zone. This is because the far field is where electromagnetic waves propagate freely.

Interaction with other energy

EM waves can interact with energy or mass in a variety of ways, including absorption, reflection, and scattering. The way an EM wave interacts depends on the wavelength and the properties of the mass at the atomic scale.

Quantum Admittance interpretations

With QA, the nearly symmetrical relationship results in nearly massless photons, satisfying Einstein’s mass-energy equivalence equation (E=mc2). The tail of the photon containing the virtual antielectrons naturally balances the electron charge by moving in the opposite direction, contributing to the overall charge balance in the universe.