The Electromagnetic Interactions of Magnets and Electrical Bodies

Note: The description of the electromagnetic interaction of electrical bodies in this scientific article will refer mainly to the electron and the proton but it can be extended to other electrical bodies in the universe. Also, only natural magnets are discussed in this article, but whatever applies to natural magnets should also apply to artificial magnets.

Background

This scientific article begins with the declaration that we are no longer looking at the North Pole or the South Pole or at the positive charge or the negative charge but at the lesser and the greater accelerations of light. This is the new way forward in our understanding of electromagnetic interactions.

Now, the possibility of dealing directly with the nature of the electromagnetic field around a magnet and that around an electrical body in a real way is something to notice as it did not apply to the magnetic field and the electric field we thought existed respectively around a magnet and an electrical body in classical physics.

In classical physics, we usually depict the magnetic field around a magnet, but it was not given a real and concrete existence. We just felt that the diagrammatic representation of the magnetic field was abstractive and probably not connected to the real nature of the field itself.

But in post-modern physics, this has changed with the introduction of the electromagnetic field as the field around a magnet and an electrical body. We are now looking at the nature of the electromagnetic field around a magnet and an electrical body in a non-abstractive manner.

Furthermore, the proposition that an electromagnetic field is what exists around a magnet and an electrical body increases our seriousness in trying to study this field because we now know that we are dealing with light and no longer its separate manifestations such as the magnetic field and the electric field.

And associated with the electromagnetic field around a magnet and an electrical body is the notion of magnitude and not mere designations like we had for the magnetic field and the electric field. It is necessary that I explain this further.

In classical physics, when we want to depict how two magnets are brought into interaction by a magnetic field, we are just concerned about the designations of the poles of the magnets and not really the magnitude of the field.

This is because we usually take that the magnitudes of the magnetic field at the poles are the same and that we only have to deal with their designations as like poles and unlike poles in order to understand how they interact.

The same also applies to electrical bodies. To describe how they interact, we usually focus on their charge signs, whether it is positive or negative, in order to understand how they interact and this is after we have concluded that they have the same charge magnitude.

This is common in our study of ‘magnetic interactions’ between magnets and ‘electric interactions’ between electrical bodies like the electrons and the protons. But this method is no longer common in post-modern physics and this is because magnets and charged bodies now interact based on magnitude and not based on mere polic designations.

In post-modern physics, we are dealing with the electromagnetic field and how it manifests itself based on the two magnitudes of the acceleration of light which are the lesser and the greater accelerations of light.

So, mere polic designations are no longer enough and the intervening field is now a real entity and not an abstract entity created only to ease our understanding of electromagnetic interactions. What we call lines of force are now more real than ever before.

We are now looking at how the electromagnetic field is responsible for the polarities of a magnet and the polarities of charged bodies and not vice-versa.

Before, we were wrongly looking at how the polarities of a magnet are responsible for the surrounding the field. The surrounding field is responsible for the distinct polarities and not vice versa.

So, in this scientific article, I will be exposing to you the true understanding of the interactions between magnets and electrical bodies based on electromagnetism and not based on magnetism or electricity. This is the background of our study in this article.

The Origin of the Two Magnitudes of the Acceleration of Light

Now that the electromagnetic field around a magnet and that around an electrical body has become a real essence not represented by mere designations, we have to become concerned about how it came to exist in the universe.

hostgator

The story goes this way: In the beginning, when the universe was being formed, it divided into the ponderable world and the electrical world.

The ponderable world was the world where light moved at a constant speed while the electrical world was the world where light accelerated.

This was how the two worlds were divided before matter was formed, and for matter to become formed it had to begin in the electrical world where we find the basic building blocks of matter.

Now, in the electrical world, the acceleration of light was of a single magnitude and this could have been in the early universe and it lasted for a very short time before something happened that would lead to the existence of matter in the universe.

What happened was that this single acceleration of light splitted into two with different magnitudes and one was the lesser acceleration of light while the other became the greater acceleration of light.

The greater acceleration of light became the one responsible for the existence of the electron while the lesser acceleration of light became the one responsible for the existence of the proton. All these happened shortly after the beginning.

I am telling you this so that you will see the relevance and also learn the habit of investigating the existence and the behaviour of matter based on the preceding field.

So, the electron and the proton exist today because of the two magnitudes of the acceleration of light and not vice versa. And the two fundamental magnitudes of the acceleration of light came about because of the creation of the electron and the proton.

Also, this is how the polarities of a magnet and of an electrical body have come to be represented by the two magnitudes of the acceleration of light and are no longer mere designations nor do they just indicate the direction of the electromagnetic field.

The polarities of a magnet and of an electrical body are no longer creations of convenience, rather they have emerged due to their undeniable existence in reality.

The Electromagnetic Interactions of Electrical Bodies

I want you to follow me carefully in the next two sections because I will be making it clear to you in a way I haven’t before how the fact that the polarities of a magnets and of charged bodies are based on the magnitudes of the acceleration of light changes how we understand their interactions which was formerly based on the superficial designations of their polarities.

Please take note of how your understanding of the universe changes as we proceed and I will be taking my vital references from the post-modern theory of electromagnetism. You may have to read this scientific article to know about this.

The diagram below shows you an electron and a proton in post-modern physics and based on their neighbouring electromagnetic field which are divided into two magnitudes.

An electron and a proton in post-modern physics

Figure 1: An electron and a proton in post-modern physics

The above diagram immediately shows that when a proton comes close to the vicinity of an electron, it comes under the influence of the greater acceleration of light, and when an electron comes close to the vicinity of a proton, it comes under the influence of the lesser acceleration of light.

The greater acceleration of light is related to the mass of the electron and for this reason, I have decided to place it in the electron while the lesser acceleration of light is related to the mass of the proton and for this reason, I placed it in the proton.

Notice that I did not say that either of the two accelerations of light is due to either the electron or the proton, but that they are related to their masses. This is because these two particles emanated from the acceleration of light and not that the acceleration of light emanates from them even though it may seem to.

So, we have that the proton responds to the greater acceleration of light that seems to be emanating from the electron while the electron responds to the lesser acceleration of light that seems to be emanating from the proton.

Again, I say “seems” because, in post-modern physics, precedence is given to the field in all of our discussions of particle interactions.

Remember our scientific story above about the origin of the two fundamental magnitudes of light in the atomic world. It is why you must understand that the acceleration of light is related to the mass of these electrical bodies but it is not due to them.

Now, the figure 2 shows the case of electromagnetic attraction between an electron and a proton.

Electromagnetic attraction

Figure 2: The electromagnetic attraction between an electron and a proton

In post-modern physics, the attraction between an electron and a proton arises because of the phase difference between the greater acceleration of light and the lesser acceleration of light existing between both of them. This basic understanding is important.

Whenever there is a phase difference in the accelerations of light between two electrical bodies, attraction ensues. Formerly, in classical physics, we are informed that the electron and the proton attract due to their reverse charges. This is not true and it is not the true understanding of electromagnetism.

Whenever there is a phase difference in the accelerations of light between two electrical bodies, attraction ensues.Click To Tweet

The electron and the proton attracts or moves towards each other when there is a phase difference in the acceleration of light between them. It then results that there is a force difference Fd between the electron and the proton.

Taking the electromagnetic force on the proton to be Fp and the electromagnetic force on the electron to be Fe, we have that the net attractive force or the force difference is,

F– F= Fd > 0

This force difference is indicated at the center of the interacting electromagnetic field between the electron and the proton, and as shown for the two attracting bodies, the force difference Fd is greater than zero. This is basically how we now understand electromagnetic attraction.

In the next diagram, we have the case of electromagnetic repulsion between an electron and another electron. As you can see and deduce from the diagram, there is no phase difference in the greater accelerations of light for the two electrons.

electromagnetic repulsion

Figure 3: The electromagnetic repulsion between two electrons

Whenever there is no phase difference in the accelerations of light between two electrical bodies, repulsion ensues. So, for this case, the force difference Fd is,

FeF= F= 0

As seen above, the electromagnetic force difference between the electron and the other electron is zero. This is why there is no attraction between them. Listen, the understanding of attraction and repulsion based on the acceleration of light changes in a radical way how we understand these two outcomes.

Whenever there is no phase difference in the accelerations of light between two electrical bodies, repulsion ensues.Click To Tweet

As you can see from above, the case of repulsion is not due to the presence of a net repulsive force between the electron and the other electron, but it is due to the absence of a net electromagnetic force.

We can boldly say that there is no such thing as a repulsive force in the universe. Electrical bodies repel because there is no net electromagnetic force between them and not because there is a net repulsive force between them.

Electrical bodies repel when there is no net electromagnetic force between them and not because there is a net repulsive force between them.Click To Tweet

The force difference in the case of repulsion is equal to zero for the interactions of two electrons and for the interactions of two protons which is shown below in figure 4:

electromagnetic repulsion

Figure 4: The electromagnetic repulsion between two protons

The diagram above shows the case of repulsion for two protons and it is obvious that there is no phase difference in the lesser accelerations of light for the two protons. The force difference Fd for this case is also equal to zero as indicated in the diagram.

FpF= F= 0

A good look at the two cases of repulsion for the two electrons and for the two protons shows that it is as though light does not want the two electrons to respond to the lesser acceleration of light and that the two protons respond to the greater acceleration of light.

This new description of electromagnetic interaction not found in classical physics is because we now have a mass dependent description of electromagnetic interactions. In classical physics, we had a mass independent description of electromagnetic interactions.

In post-modern physics, the concept of the electric field has become replaced by the electromagnetic field for all electrical bodies.

Let’s now proceed to the electromagnetic interactions of two magnets.

The Electromagnetic Interactions of Magnets

Our understanding of the electromagnetic interaction of two magnets is derived from our understanding of the electromagnetic interaction of electrical bodies presented above.

Both the electromagnetic interactions of electrical bodies and magnets are governed the same by the acceleration of light.

In the diagram below, you are looking at a magnet according to post-modern physics. And as you can see, the two poles of the magnets are designated based on the two magnitudes of the acceleration of light.

A magnet

Figure 5: A magnet and its surrounding electromagnetic field according to post-modern physics

These two different magnitudes of the acceleration of light are what creates a phase difference between both poles necessary for an electromagnetic field to exist around the magnet as shown.

Remember, that in post-modern physics, the concept of the magnetic field has been done away with and it has become replaced by the electromagnetic field. So, you have that a magnet is depicted as above in post-modern physics.

I want you to look carefully and enthusiastically at the above diagram of a magnet because it is what we will have in this post-modern era. Observe the two poles of the magnet and how they are designated based on the two magnitudes of the acceleration of light.

Now, in classical physics, the magnetic field is said to exist around a magnet due to the aligned, internal spin of the electrons of the magnet. While we still make reference to spin, there is a different twist to it in post-modern physics.

In post-modern physics, we have that the electromagnetic field around the magnet is what is associated with the aligned spin of the internal electrons and not the magnetic field.

And because we give precedence to the field as a tradition in post-modern physics, we have that the electromagnetic field is responsible for the aligned, internal spin of the electrons and not vice versa.

According to the diagram above for a magnet in post-modern physics, the direction of the electromagnetic field is taken from the pole of lesser acceleration of light to the pole of greater acceleration of light and this follows the direction of the tangents of the aligned spin of the electrons which should point away from the pole of greater acceleration of light to the pole of lesser acceleration of light.

Now, beyond that let’s look at how two magnets interact though it is the same as that of electrical bodies.

electromagnetic attraction between two magnets

Figure 6: The electromagnetic attraction between two magnets

As shown above, when two magnets of unlike poles in the sense that one magnet has its pole of greater acceleration of light ac> facing the pole of the lesser acceleration of light ac< of another magnet, we would have that both magnets become attracted to each other.

In this case of attraction, just like the case for attraction for electrical bodies, the phase difference of the greater and the lesser accelerations of light is greater than zero. For magnets and during attraction we can write the force difference as,

F> – F< = Fd > 0

So, there is attraction between two magnets when there is a net electromagnetic force Fd between them. But when two poles of the same magnitude of the acceleration of light are placed to face each other, there will be repulsion.

There is attraction between two magnets when there is a net electromagnetic force between them.Click To Tweet

This is shown below for two poles of the lesser accelerations of light.

electromagnetic repulsion between two magnets

Figure 7: The electromagnetic repulsion between two magnets

Similar to the case of repulsion for two electrical bodies, for the two magnets, there is repulsion because there is no phase difference in the accelerations of light.

For this case where two poles of lesser accelerations of light are placed to face each other, the force difference is zero as presented below:

F< – F< = Fd = 0

The above is the same result when two poles of greater accelerations of light are placed to face each other as shown in the next diagram.

There can be no phase difference or net attractive force between two poles of lesser accelerations of light or two poles of greater accelerations of light and this is what causes repulsion for two magnets.

So, even for two magnets like for two electrical bodies, repulsion is not due to the presence of a net repulsive force but it is due to the absence of a net electromagnetic force.

electromagnetic repulsion between two magnets

Figure 8: The electromagnetic repulsion between two magnets

This is simply represented below for the two magnets which have their poles of greater acceleration of light facing each other as shown in the above diagram,

F> – F> = Fd = 0

According to the above, there is repulsion between two magnets when there is no net electromagnetic force between them. It is important for us to see how for both electrical bodies and magnets attraction and repulsion are not due to opposite forces like we had thought in classical physics.

There is repulsion between two magnets when there is no net electromagnetic force between them.Click To Tweet

Attraction is due to the presence of a net electromagnetic force while repulsion is due to the absence of a net electromagnetic force. This sums up what has been said in the last two sections.

Attraction is due to the presence of a net electromagnetic force while repulsion is due to the absence of a net electromagnetic force.Click To Tweet

We have therefore established that just like for electrical bodies, magnets interact the same based on the acceleration of light.

Crucial Discussion

The concept of the acceleration of light changes how we understand the interactions of magnets and electrical bodies. The concept of the acceleration of light unifies the interactions of electrical bodies and the interactions of magnets as being due to electromagnetism.

Formerly, we thought that an electric field existed around electric bodies and that it was responsible for their interactions and that a magnetic field existed around magnets and that it was responsible for their interactions.

But now we see that the electromagnetic field is what exists around electrical bodies and magnets. I want you to really see this unforeseen unity of electricity and magnetism.

We now designate the poles of a magnet and that of electric bodies based on the two magnitudes of the acceleration of light. This is the true way of designating what we had separately called electrical and magnetic poles.

Aceleritas, the acceleration of light, has come to replace all other concepts attributed to its effects. We now have only electromagnetism and gravitation in the study of the effects of the components of the unified field.

What has been shown to you above is how light is responsible for the interactions of magnets and electrical bodies. This is the new post-modern understanding of the interactions of magnets and electrical bodies.

All of their interactions are electromagnetic interactions.

Summary

This scientific article shows you the electromagnetic interactions of magnets and electrical bodies. It is a new approach towards understanding these fundamental interactions.

Post-modern physics is informing us that light has been involved all these while and that it is the field around these bodies just like we think of gravity as a field around bodies.

The interactions of both magnets and electrical bodies are due to the accelerating electromagnetic field which its magnitude has been divided into the lesser and the greater magnitudes.

These two magnitudes of the acceleration of light now constitute the poles of magnets and electrical bodies and they are what has led to the concept of a net electromagnetic force. So, according to this scientific article:

1. When two electrical bodies or two magnets attract each other, they do so because of the presence of a net electromagnetic force.

2. When two electrical bodies or two magnets repel, they do so because of the absence of a net electromagnetic force.

Post-modern physics is informing us that the field around a magnet is light (accelerating light) and not a magnetic field and that the field around an electrical body is also light (accelerating light) and not an electric field.

Just like we really recognize gravity as an undivided field, so is post-modern physics making us realize that light is an undivided field. There is no such thing as a magnetic field here and an electric field there.

There is only an ever unified electromagnetic field and this is what has led to the unified understanding of the interactions of magnets and electrical bodies.

Until next time,

I will be here.

– M. V. Echa



M. V. Echa

M. V. Echa

My message is the universe, my truth is the universe, and this blog contains all you need to know about the universe, from the true nature of reality to the long-sought unity of the cosmos — which is the big picture!