Even if the detection equipnt is highly precise, it is not easy to detect the instantaneous changes in the Voidon jump within the overlap area of gravity and Z-wave.
The main reason is that the location of the detection equipnt cannot be within the coverage area of the Z-wave; otherwise, the Voidon jump acceleration effect produced by the Z-wave region would directly target the detection equipnt itself, rather than producing normal effects.
This is much like the molecules in the air, which, within the Z-wave coverage area, are not subject to more gravitational effects but are instead affected by the compression effect itself.
The area covered by the Z-wave is a distinct region, separated from others, and possesses unique physical properties.
Therefore, the detection equipnt can only be placed at the edge of the Z-wave coverage area, the boundary line between the region and the outside world.
On the boundary line of the Z-wave coverage area, theoretically, there is still so influence from the active Voidon jumps, but the degree of this influence is not substantial.
This is one of the reasons why detection is limited.
Another reason is that the influence of active Voidon jumps on enhancing gravity is very slight; the instantaneous enhancent of gravity is just a secondary manifestation of the increased activity in Voidon, which mainly exhibits in material compression.
If there is material inside, the focus will be on the squeezing of the material, rather than on gravity enhancent. However, nothing is perfect, and the boundary line between the Z-wave area and the outside world will still be subject to so collateral effects from the internal reactions.
This is the key to detection.
Clearly.
The experint needed to be designed with great precision, especially the control of the Z-wave area and the placent of gravity generation equipnt and high-precision detection equipnt—all had to be controlled with great precision to achieve the desired results.
When combined, several factors made it clear that the experint was not so simple.
When the experint began, everyone watched the values on the detection equipnt, and the first trial disappointed them; the values did change, but only slightly, to be exact, by only 0.015.
This was asured in ’milliters’.
Such a minor change could almost be considered aningless, as even the impact of environntal factors, such as a light breeze, could cause greater fluctuations in the values. Without considering air influence, the location of the high-precision detection equipnt and the vibrations caused by other equipnt turning on could also cause minor variations in the values.
After turning on the Z-wave once, a period of waiting was necessary.
The experintal group imdiately made so fine adjustnts to the balance position of the detection equipnt, hoping to achieve perfect equilibrium with the edge of the Z-wave coverage area.
Perfection, of course, does not exist.
For the experint to yield results, a asure of luck was still needed.
The second and third trials failed in succession.
After witnessing the third failure, many felt very disappointed, believing that the experintal design might be flawed. Perhaps, if they had used ’air pressure’ detection, the results would have been slightly better.
But Zhao Yi dismissed the ’air pressure’ detection thod, "Air pressure detection takes too long to prepare, and it might not yield any results."
"We are currently conducting direct physical tests, and I believe there is no issue with the experint itself. If it were conducted on the moon or in space, we’d already have clear results."
He was referring to the lack of intensity.
To be precise, the intensity of the Z-wave wasn’t enough. A re three hundred-fold compression was indeed too little.
Under an environnt without air influence, the sa Z-wave power would easily achieve compression rates of tens of thousands, millions, or even tens of millions and hundreds of millions.
In the absence of mass-bearing materials, both the coverage area and the rate of compression of the Z-wave region would exhibit an exponential increase.
Zhao Yi’s decision was to continue with the experint. He personally supervised the placent of high-precision detection equipnt and sought out the balance point himself.
After more than an hour of effort, he finally found a position close to ideal.
Then, the experint continued.
This was the fourth trial of the day. Both the Z-wave device and the gravity generation device had been activated four tis, consuming an astonishing amount of energy, with wear and tear so severe that the energy supply was no longer sufficient.
As the experint officially began, once again all eyes were on the changing values.
Finally, the values jumped.
Instantly, soone exclaid, "0.8!"
"It is really 0.8!"
"0.8, that’s a significant number, right? It proves that Z-wave coverage can enhance instantaneous gravity."
"We’ve succeeded!"
Many people exclaid excitedly.
Zhao Yi wasn’t surprised by the results because he knew the theory was definitely sound, and having personally adjusted the equipnt, he was quite confident about the experintal outco.
The current change in value had reached 0.8, sufficient to prove that active Voidon jumps could cause instantaneous changes in gravity. With this conclusion, they could now study the precise relationship between Z-Wave Compression ratios and instantaneous gravitational fluctuations according to the principle.
Based on their relationship, ultra-high ratio Z-wave detection could be achieved.
This experint was a success.
In fact, they needed more surprising experints, as their research was aid at technology, not rely proving sothing.
They didn’t need to publish papers or seek clearer evidence for this.
Therefore, the research could directly enter the technological phase, conducting studies in space or at the Lunar Base rather than on Earth’s surface, because the Earth’s air-filled environnt was not suited for this research.
After the experint concluded, Zhao Yi held a summary eting and then had everyone write their reports.
Submitting reports and applying to conduct research in outer space or on the Lunar Base were the next steps, with superiors allocating targeted funding and support from various institutions to kick off a series of R&D initiatives.
Once the theory was confird to be without any issues, a technological breakthrough was just a matter of ti.
----
The experintal base had continuously overco gravity generation and Z-wave detection technologies, to everyone’s great surprise.
Both were crucial technologies for space exploration.
By now, the technologies related to space exploration could be considered perfected, and further significant breakthroughs were unlikely.
In fact, Zhao Yi hoped for further breakthroughs in the field of matter transmission, but Earth seed sowhat insufficient for continued research.
One reason was the significant impact of environntal factors, and another was the imnse energy consumption and scale of the experints.
Conducting simple matter transmission research was already an international cooperative project worth hundreds of billions.
Expanding the research would definitely require increasing the scale of experints to reach new conclusions, necessitating greater investnt, while Earth’s surface was not suitable for long-term risky matter transmission experints.
Thus, Zhao Yi thought about continuing R&D later. You have to take things step by step; wait until space exploration enters a new phase, or the Lunar Base expands, or establish new extraterrestrial bases, before continuing matter transmission experints.
He believed that the principles of matter transmission were complex and potentially related to the ultimate principles of the universe. To achieve major breakthroughs in related technologies, other sciences may need to be perfected first to make it even slightly possible.
Investing heavily in matter transmission research now seed a bit too costly for the potential benefits.
Because they had more important things—perfecting technologies related to space exploration, applying gravity generation technology, and Z-wave detection technology to make spacecraft capable of true intersystem travel.
That was of utmost importance.
With substantial investnt in R&D, the gravity generation devices were soon applied to spacecraft, including the Xuanhuang, the Space Agency’s three new ships, the Mars-1 spacecraft, Yixing’s one security shuttle and three transport vessels, and even two sightseeing ships, all fitted with gravity generation devices.
Next were the most important cosmic ships.
Installing gravity generation devices on cosmic ships was much more complex, as their structures were huge, they contained very advanced equipnt and technology, and internal modifications took nearly eight months.
During those eight months, Z-wave detection technology was also perfected, capable of detecting compression ratios for the spacecraft to cross distances of ga-kiloters and above.
Once the new Z-wave detection device was installed on the cosmic ships, they beca true cosmic vessels, capable of freely shuttling between star systems.
At the eting discussing the cosmic ship’s exploration of nearby star systems, Zhao Yi took over technical command and declared with certainty, "Our plan is to arrive at the nearby Sagittarius constellation with eight jumps, within a week."
"Our destination this ti is the planets Sagittarius RC-03, RC-03, and RD-01."
"We will cross the star system to reach Sagittarius and explore three planets, gathering as much information as possible. If necessary, we’ll also perform landing operations."
"This will mark the beginning of humanity’s conquest of the Milky Way, the conquest of the universe—"
"I am convinced that we will complete the mission successfully!"
Three days later.
Under the watchful eyes of the entire world, the cosmic ship carrying three thousand pioneers of space exploration slowly ascended and swiftly headed toward the unknown.
Everyone believed that,
this mont would beco the symbol of entering a new era!
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