Free Web NovelChapter 1199: Chapter 582 I’m Very Focused, Alright!_1
Magnetic fields are exceedingly complex to analyze.
From a conventional physics perspective, magnetic fields are related to electromagnetic force, meaning that analyzing magnetic fields is tantamount to analyzing electromagnetic force.
Since the completion of the Boundary Theory for particles, the only force that has been fully analyzed, involving the concept of "mass points," is gravity.
Zhao Yi had previously conducted research on the strong force, which can be regarded as the result of space exerting a special affinity on the energy configuration, producing compression.
But that was all.
Although gravity and the strong force were unified through the theories of spatial compression and mass points, in actuality, the part related to the strong force was still very limited, with only some mathematical descriptions.
Because the strong force is directly tied to the internal structure of atomic nuclei, a true analysis involves numerous factors. When it comes to atomic structure, both the weak force and electromagnetic force are inescapable. As particle physics continues to evolve, the accuracy of some theories remains uncertain. Any analysis based on these may yield incorrect results.
Therefore, the only force that has actually been fully analyzed is gravity. freёwebnovel.com
Analyzing magnetic fields—or electromagnetic force—using conventional mathematical theories is definitely an exceedingly complex task.
In fact, with the current foundational knowledge, it is almost impossible.
Zhao Yi embarked on his research from the perspective of spatial analysis, deriving the mathematical expressions for magnetic fields through the characteristics of space, the relationship between space emitting Z-waves, and magnetic fields.
This equates to studying the "low-profile" from a "high-end" starting point. In relation to space, magnetic fields indeed occupy a "lower-tier position."
Zhao Yi was absolutely certain that the characteristics of space were fundamental to the emergence of the four forces.
Gravity is directly related to the compression of space. freёwebnoѵel.com
The strong force is also the result of space compressing energy points.
Consequently, one can roughly assume that electromagnetic force and magnetic fields must also be directly related to space or changes brought about by spatial characteristics.
By using the characteristics of space and space-emitted Z-waves to express magnetic fields capable of absorbing Z-waves, and then referencing a large amount of experimental data, one can deduce the relevant expressions. However, the deduction process remains complex, with the main difficulty being the establishment of the mathematical relationship between spatial Z-waves and magnetic fields.
If the theory of spatial analysis is to be further refined, the further analysis of magnetic fields and Z-waves is undoubtedly an essential aspect to address.
After a series of analytical studies, Zhao Yi discovered that magnetic fields are related to space and also mass-bearing particles, unlike gravity, which is directly produced by the spatial compression of mass points.
"So, magnetic fields are different from gravitational fields. Their forces are not emitted by space..."
Space compresses matter, forming gravity.
Magnetic fields, however, are not formed by "spatial characteristics," but seem to be more significantly related to mass-bearing particles, which suggests that magnetic fields are a force that lies between space and matter.
Magnetic fields can absorb Z-waves, just as matter can absorb energy.
"From this angle..."
Zhao Yi carefully examined the equations on the paper, then suddenly furrowed his brows tightly. He pulled out several sheets of draft paper from underneath, flipping through them one by one, and comparing them to the equations for analysis.
Quickly.
He came to a surprising conclusion, "There’s a loss in Z-wave energy? And a significant portion of it is missing?"
"That’s not right!"
"That can’t be possible. How could there be a loss of Z-wave energy..."
Zhao Yi immediately used the "Law of Cause and Effect" to confirm that there indeed was a loss in the Z-wave energy.
This loss refers to the energy released by Z-waves as compared to the energy absorbed by magnetic fields and ionized matter.
If it’s a conventional Z-wave emission experiment, where there’s no special magnetic field or ionized or particle matter to specifically absorb the Z-wave energy, the loss after release is even greater.
It could be as high as one hundred percent!
"How is that possible?"
"Which means, under normal conditions, Z-waves only transmit over a few kilometers, but the energy isn’t absorbed by Earth’s magnetic field; it just dissipates?"
"Where does it go?"
He pondered carefully and felt that the result made sense.
Think about it.
In a blocked spatial state, magnetic fields absorb the energy of Z-waves, and once the blocking effect of space is gone, the strength of the magnetic fields would decrease back down.
In other words, under conventional conditions, magnetic fields don’t directly absorb the energy of Z-waves.
So, the question arises—
"If Z-wave energy isn’t absorbed by conventional magnetic fields, and it isn’t absorbed by air or ordinary particles either, why can it only cover a few kilometers under normal circumstances?"
"If the energy isn’t absorbed, the transmission distance should be infinite."
"Where did the energy go?"
There are only a few possible directions for energy to go: it’s either absorbed by particles, absorbed by magnetic fields, or absorbed by space.
Particles and magnetic fields have been directly ruled out, leaving only space.
Using the "Law of Cause and Effect" also yielded an accurate answer—space.
But why? It’s strange.
Although space releases Z-waves, why would it absorb them again, and most importantly, there seems to be no reaction from space.
In anti-gravity devices, space also absorbs energy, creating a ’spatial blocking’ effect.
The energy intensity of Z-waves is not low.
If the energy is absorbed directly by space, theoretically, there should be some detectable changes.
Without any changes, it’s too strange.
"Could it be because the energy intensity is too low? Any reactions are too slight to notice?"
Zhao Yi found it somewhat perplexing.
...
The missing energy from the absorbed Z-waves is undoubtedly a very significant issue.
