Free Web NovelChapter 1371: Chapter 654: Respectable Elder
The research on "Z-Wave Detection Technology" began with the detection of controllable charged particle beams, with the method relying on a small electronic gun to release Z-Wave Compressed electron beams in a vacuum environment, and conducting energy detection after compression.
Charged particle beams are constrained by high magnetic fields and will travel at high speeds along fixed arcs, ultimately hitting the target where electrical charge is measured.
Particles compressed by Z-Waves exhibit a significant increase in activity, which is made evident by a noticeable increase in electric charge.
Firstly, it’s essential to determine the charged amount of the electron beam, conduct Z-Wave Compression, and then perform another detection. By analyzing the differences in electrical charge between the two detections and comparing the compression ratio of the Z-Wave, a certain result can be obtained.
This was the easiest, most controllable, and result-oriented method developed through collaborative research in the laboratory.
The principle of the experiment is not complex; the main difficulties lie in two aspects—first, the confinement of the electron beam. Achieving a fixed rotation of the electron beam requires an extremely strong magnetic field.
This poses a great difficulty.
Like the initial magnetic confinement methods in controlled nuclear fusion, achieving that level of confinement would necessitate massive equipment and a substantial amount of financial support, which is obviously not permissible in an experimental setting.
However, for Z-Wave-related detection, there’s no need for perfect confinement of the electron beam. It is enough if the electron beam doesn’t stray from the experimental vacuum range, or in other words, doesn’t hit the edges of the vacuum environment, even if just for 0.5 seconds or less.
With that, the difficulty is significantly lowered.
The main focus of the experimental design still revolves around how to ensure that the electron beam is affected by magnetic forces coming from various directions within the high-intensity magnetic field surrounding the vacuum environment, continuously changing direction.
It took over half a month to complete this task with great difficulty.
The second challenge lies in analyzing the relationship between the increase in electrical energy and the spatial compression rate.
Between the increase in electrical energy and the spatial compression rate, there exists a "particle compression ratio." Ultimately, the goal is to determine the relationship between the particle compression ratio and the spatial compression rate.
Since no related research had been conducted before, everything had to start from scratch, involving a process of repeated experiments, data recording, and various mathematical analyses along the way.
The research process was relatively straightforward, but everyone was enthusiastic, as opportunities to engage in entirely new research aren’t common. Especially with Z-Wave Detection Technology, which is directly connected to the cosmic spacecraft project, its importance is unquestionable, and everyone hoped to achieve results.
The research on "Z-Wave Detection Technology," from its initiation to the conclusion of the first study, took about three months.
During this period, many events happened, such as the successful launch and operation of the third and fourth Energy-Gathering Satellites around the sun into their predetermined orbits.
For example, Yixing Company achieved a breakthrough by manufacturing 50,000 units of the Unlimited Power Automobile.
Moreover, a small space shuttle’s manufacturing plan was finalized and entered into rapid production.
And so on.
Zhao Yi and other researchers immersed themselves in experimental research, repetitively conducting experiments and meticulously recording all data.
After three months, they finally achieved certain results, discovering that electron beams could indeed be used to detect spatial compression rates, although with limitations.
In the laboratory-created vacuum environment, a small electron beam could detect spatial compression rates of about thirty million at most.
Thirty million is a significant rate, but it fell far short of Zhao Yi’s expectations.
Initially, Zhao Yi had hoped to use detection technology to immediately detect spatial compression rates exceeding one hundred million in order to enable rapid space shuttle traverses within the solar system and its vicinity.
Clearly,
using electron beams for detection was not feasible.
Even in a real space environment, supported by high-power nuclear fusion reactors, the spatial compression rate that an electron beam could theoretically detect was only limited to about fifty million at most.
"Fifty million is a very good figure and can be used directly, but the rate still falls short and has not met expectations," Zhao Yi said with some regret at the internal meeting marking the end of this phase of the laboratory experiments. "However, our research has proven that the maximum detection rate for electron beams is only fifty million, and it can’t go any higher."
The determining factor for the detection rate’s upper limit was the increase in electrical energy. Through continuous experiments, they found that simply increasing the compression ratio did not significantly increase the electrical energy. freёwebnovel.com
Although there was a positive correlation between the two, it was not directly proportional but rather looked like a parabola with a peak.
If the compression ratio continued to increase, the increase in electrical energy would no longer be significant and would even decline exponentially afterward.
The electrical energy continued to increase, but the increments were minimal.
"This is because once the compression ratio grows beyond e, it reaches a balance with spatial compression."
"The magnetic field is a form through which particles resist spatial compression, but when there’s no longer a need to increase the magnetic field to counteract spatial pressure, the field will increase very slowly."
"Magnetic fields and electric fields are inseparable; the two are interrelated."
"Therefore, once the compression ratio goes beyond e, the subsequent increase in electrical energy will start dropping exponentially."
That’s the reason behind the conclusion that the highest detectable compression rate is around fifty million.
When incremental increases show an exponential decline, calculations are based solely on analyzing the minute fractions at the decimal’s end, which is terrifying because it quickly escalates to substantial computational demands to determine the incremental values.
