In spire is short for in-a-spiral

The word pneuma comes from the ancient Greek verb pneo (πνέω), which means

In spire or "to breathe".:.where 

Breath and breathing are spiral motions

Classical Medicine: It was understood as a vital, invisible liquid or vapor necessary for life and the maintenance of bodily functions.

Theological Meanings

The Holy Spirit: In Christian thought, pneuma is most frequently used to refer to the Holy Spirit, the third Person of the Trinity, according to Bible Hub. 

Individual Spirit: Pneuma can also denote the human spirit or soul, the animating principle by which a body is alive and capable of thought, feeling, and action. 

Homer: E-motion or in spiral "pressure"

Homer's epics predate "modern scientific"

Study of the physical world. 

His use of language for "pressure" refers to psychological and spiritual in spiral states. 

Thymos (θῡμός) and menos (μένος) describe an intense emotional or spiritual spiral force within a character. 

Oxidation electron as photon emission

Reduction autoprotolysis dissociation 

An oxidation-reduction (redox) reaction involves the transfer of electrons between chemical species, changing the oxidation number of a molecule, atom, or ion. 

Oxidation is the loss of electrons, while Reduction is the gain of electrons.

 Redox reactions are vital to life, including photosynthesis, respiration, and combustion.

 Here's what to know about redox reactions: 

Process Redox reactions involve the transfer of oxygen, hydrogen, or electrons as ions 

Characteristics Redox reactions are coupled, meaning that oxidation always occurs with a reciprocal reduction. 

They also involve a net chemical change, where an atom or electron moves between units of matter. While units  of matter are determined by geometric distribution of electrons an idea 

Circled by the perfect circle containing protons arranged orthogonally to each other around

The circumscribed circumference

Examples Redox reactions include the rusting of metals, browning of fruit, and burning of fuels and all Photons as light

Substances Redox reactions involve an oxidizing substance that loses electrons 

Gaining organization and positive charge

and

 a reducing substance reduced in 

Positive charge  by 

The gaining of electrons 

Causing a new neutral or negative charge

The closest translation is a passionate "spirit" or "anger" that can drive a person to great deeds.

The 13.6 electron volts required to dissociate H into OH- and H3O+

 A thymos is often described as feeling like a gas under intense pressure within the phren (lungs), which holds this life-force.

The pulsation of the breath is the path traveled from 13.6 to the Planc length or

1296/1080

As the idea of 36x6x6 / 36 x 6 X 5 the 

Volume defining interval separating 

All charge centers

Homeric heroes feel "pressure" as a form of internal torment and conflict. For example, in The Odyssey, Odysseus commands Eurycleia to "rejoice in [her] thymos" rather than publicly celebrate the deaths of the suitors. 

Every dissociation of H2O forms the basis for the formation of a new ion with new energy.

Here's a breakdown of the process:

Ionization: A hydrogen atom consists of a proton and an electron. 

The electron is bound to the proton by an electrostatic force of 13.6.eV

 To ionize the atom, an energy of 13.6 eV is supplied to the electron, allowing it to escape the atom's nucleus and become a free electron. This results in a positively charged proton (H+) and a free electron. 

Recombination: To reverse this process, the free electron needs to be captured by the proton, forming a neutral hydrogen atom. This occurs when there is a pathway for the excess energy (the kinetic energy of the free electron of 13.6 eV) to form the new bond allowing the electron to settle into a bound state. 

What is required:

A negative charge (the electron): 

The fundamental charge to form the neutral atom is a single electron, which has a negative charge.

Removal of kinetic energy:  the kinetic energy of the free electron 

K = 1/2 x mass x length converted to area

m = 0.511 megaelectronvolts (MeV)

     = 511000 eV

v   = 160.2176634×10^-21 Coulombs

Coulomb =   6.241509×10^18 e

The SI defines the coulomb as "the quantity of electricity carried in 1 second by a current of 1 ampere" by fixing the value of the elementary charge, e = 1.602176634×10−19 C.[3] Inverting the relationship, the coulomb can be expressed in terms of the elementary charge

When the free electron encounters the proton, it needs to "slow down" or release its excess kinetic energy to be captured into a lower energy level. This energy is typically released as a photon in a process called radiative recombination. 

Plato: Philosophical and physical descriptions of pressure

Plato, writing centuries after Homer, moved from a purely spiritual explanation toward a more physical one with clear definitions arrived at via deduction and logic. He explored different ideas related to what we would today call pressure. 

Atmospheric pressure: The ancient Greeks were aware of the physical effects of air. 

The philosopher Anaximenes (c. 6th century BCE), for example, theorized that matter was made of air that became denser under pressure. While Plato did not describe this concept in detail, he would have been aware of the philosophical discussions around the weight and substance of air, represented by words like pneuma (πνεῦμα), meaning "breath" or "spiral motion observed in wind"

Population pressure: Plato described the pressure of overpopulation in his political philosophy. In The Republic, he explored the tension between population size and the city's resources. Later accounts attribute a lost hymn by Homer, referenced by Plato, that blames the Trojan War on the gods seeking to relieve the "deep-bosomed earth" of the crushing "tribe of men".

Social and political pressure: Plato's philosophical inquiries into political compulsion and social pressure come closer to a modern, figurative understanding of the term.

In The Republic, Plato discusses how an "excess of liberty... seems only to pass into excess of slavery" and how desires can overwhelm an individual, acting as a form of tyranny or internal pressure.

Later, in the 20th century, philosopher Martha Nussbaum would argue that Plato's writings put "heavy pressure" on democratic societies to justify themselves against his critiques. 

For a bare helium atom, the first ionization is 24.6 eV; for a singly ionized helium atom (He⁺), the second ionization energy required to convert the double bond to a lone proton  is 54.4 eV. 

Sources of the electric field:

The two primary sources that define and create the electric field of a system are: 

Electric charges: An unionized  electric charge is the most fundamental source of a spiral in a spiral inspirational electric field.

Positive charges: Create an electric field that radiates outward, repelling other positive charges attracting negative charges

Negative charges: Create an electric field that radiates inward, attracting any positive charges

Repelling negative influences

Changing magnetic fields: A time-varying magnetic field can induce or produce 

Or generate  an electric field, a principle described by Faraday's Law of Induction. 

For a system with a simple, static charge distribution, the electric field is determined by: 

Magnitude of the charge: A larger charge creates a stronger electric field.

Distance from the charge: The field's strength decreases with the square of the distance from the source charge, following an inverse-square law.

Currents as a cause

Magnetic flux is caused by currents, i.e. by the movement of charges. Currents will always create closed field lines. 

The magnetic flux, therefore, has no beginning and no end. 8 Θ Φ

 Τhere are no sources or sinks of magnetic flux density and magnetic flux. They only exist as spirals creating spheres with certain centers arranged in certain geometric magnetic 

Arrangements 

 His work demonstrated that voltage is only induced when the magnetic field is changing, and that the magnitude of Voltage depends on the rate of change of the magnetic flux. 

Demonstrating

Demonstrating the effect with a magnet and a coil

A common and simple modern version of one of Faraday's experiments uses a bar magnet and a coil of wire connected to a galvanometer, which is a sensitive device for detecting and measuring small electric currents. 

The experiment demonstrates the relationship between motion, magnetic flux, and induced voltage:

Stationary magnet: When the magnet is held still, whether inside, near, or far from the coil, the galvanometer shows no reading. This proves that a steady magnetic field, or one that is not changing, does not induce a voltage.

Moving magnet: When the magnet is pushed into the coil, the galvanometer needle deflects, indicating that a voltage has been induced and a current is flowing through the wire.

Faster motion: The faster the magnet is moved into or out of the coil, the greater the needle's deflection, demonstrating that a higher rate of change in magnetic flux produces a higher voltage.

Opposite direction of motion: When the magnet is pulled out of the coil, the needle deflects in the opposite direction. This shows that the direction of the induced voltage and current depends on the direction of the change in magnetic flux.

Reversing poles: If the magnet is flipped so the opposite pole is moved into the coil, the needle will again deflect in the opposite direction from the original motion, confirming that the induced voltage depends on the orientation of the magnetic field. 

Faraday's iron ring experiment

In one of his initial and most significant experiments in 1831, Faraday used two coils of wire wound around an iron ring. 

He connected the first coil to a battery and the second coil to a galvanometer.

When he connected the battery to the first coil, the galvanometer briefly showed a current in the second coil, then returned to zero. When he disconnected the battery, the galvanometer briefly showed a current in the opposite direction.

This proved that it was not the current itself that caused the induction, but rather the change in the magnetic field caused by the current starting and stopping. The iron ring concentrated the magnetic flux created by the first coil, allowing it to induce a voltage in the second coil. 

The Faraday disk

Faraday also famously constructed a "homopolar generator" known as the Faraday disk. 

A copper disk was rotated between the poles of a magnet.

By connecting electrical contacts to the center of the disk and its rim, he demonstrated that a constant electric current could be produced by a spinning conductor moving through a stationary magnetic field. This device was the first electric generator. 

The definition of the tesla is based on the force exerted on a conductor resisting  carrying a current in a magnetic field: a magnetic field of one tesla will generate a force of one newton per meter of conductor when it carries a current of one ampere