In terms of future exploration of the universe, Z-wave detection technology is extrely important.
The principle of this technology is also very simple. It involves finding a specific type of matter and asuring its compression rates under high magnifications. The obtained nurical values of compression can then be used to extrapolate the rate of space compression.
The mass of the matter searched for cannot be too high, as it would directly affect the compression rate. Simultaneously, the mass cannot be too low; if only a few particles are compressed, no matter how high the compression rate, it won’t be possible to detect with detail.
While the principle sounds simple, finding the suitable matter is the most challenging part.
The compression rate of matter has a certain relationship with the space compression rate, yet, when analyzing different matters, no definite relationship can be established.
For example, a certain type of matter in an environnt compressed by a hundredfold might only experience twofold compression. For most tallic substances under fivefold compression, they are likely in an environnt with around two hundredfold space compression.
These are the conclusions drawn from Z-Wave Compression experints.
Relative to tallic substances, gas particles exhibit much smaller compression rates. For instance, in the sa environnt with two hundredfold space compression, most gas particles are only compressed between one to two tis.
One to two tis compression has not reached the critical value ’e’ needed to counter space compression rate, and when placed back into a typical environnt, they quickly return to their original state.
Whether it’s air or tal particles, when placed in cosmic space and subjected to ’100 million tis’ or higher exponential compression rates, the compression rate doesn’t greatly increase due to the varying intensity of energy.
When the energy intensity of Z-waves is focused on compressing space, the resulting force exerted on the compression of particles in space is not very strong.
For example, in an environnt of one hundred million tis compression, if tal particles were to suddenly enter it, they might only be compressed two or three tis.
In the sa environnt with one hundred million tis space compression, with the sa tal particles entering, they might be compressed five or eight tis.
The sa environnt yielding different results, the difference lies in the Z-waves being spread out in cosmic space, covering such an extensive area that it inadvertently causes the regional compression ratios to not be very high.
This can be understood as follows: The compression of space by Z-waves is a whole, yet taking out a single region does not represent the entirety.
Therefore, to accurately calculate the overall compression rate, dynamic matter is still needed.
For instance, proton beams close to the speed of light.
There is a duration to the Z-wave space compression, and for proton beams near the speed of light, they can travel a considerable distance within this duration.
Thus, the compression rate experienced by electrons can reflect the compression situation in a local region. From there, through a series of complex calculations and the established relationship between overall and regional compression rates, the overall space compression rate can be calculated.
These are the basic principles.
Clearly.
Attempting to detect the compression rate of proton beams near the speed of light is extrely difficult because once the proton beam is emitted, it’s very hard to perform the necessary detection in ti.
This is a minor research direction.
The second research project Zhao Yi decided to undertake is directly related to matter transmission technology.
Previously, he had always believed that matter transmission technology could only be used for the transmission of information. Later, he discovered it could also transfer light energy and hence, probably other forms of energy too. However, since the transmission of other energies seed less significant and the difficulty substantially higher, research did not continue much further.
The research Zhao Yi is about to undertake is based on the transfer of energy, extending the inquiry to whether it’s possible to transmit matter.
Matter transmission is entirely different from energy transmission.
In original research, energy was regarded as extra-dinsional, while mass was a product of higher dinsions.
Extra-dinsional and higher-dinsional are not the sa concepts. The forr is not affected by dinsions, whereas the latter is repelled in the three-dinsional universe, or it can be understood that the three-dinsional universe cannot accommodate the mass of higher dinsions.
But since energy can be transmitted through space, it leads to the investigation of how to enable matter to be transmitted through space.
Of course.
This research might not necessarily yield results; perhaps it will turn out to be nothing but a pipe dream in the end. However, the process of research is what is most important.
Even if it turns out that matter cannot be transmitted, the process will surely yield many findings that will help deepen the analysis of space and the understanding of dinsions.
The latter is content for long-term research.
Zhao Yi still decided to first develop Z-wave detection technology.
This involves both theory and technology.
However, carrying out the research is far from easy. He needs a very professional laboratory, a precise Z-wave Generator, and while the strength of the Z-waves doesn’t need to be too great, the precision of their emission must reach computer-controlled accuracy, rather than being manually controllable.
Additionally, the laboratory must also be able to create a vacuum environnt to simulate the cosmic environnt.
At the sa ti, he’ll need a large number of the most refined detection instrunts.
And so on.
As there are currently no such laboratories in the country, he’ll have to build a new one.
So, Zhao Yi went to Zhengyang University.
Zhao Yi ca to Zhengyang University openly, under the guise of a visit, and many people from the university ca to greet and entertain him.
Among them were the familiar Vice-Chancellor Liu Zhibei, several directors and professors he knew, and the leader was the President of Zhengyang University.
The President of Zhengyang University is Ying Ye, who is not only the university president but also takes on administrative work in the city and province. Because of this, his work is extrely busy, and he rarely spends a calm day in the university during the week.
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