Free Web NovelChapter 1231: Chapter 594: The Law of Conservation of Mass-Energy is No Longer Working!_1
Liu Jiankun was indeed very proactive about the new company because he knew that the space shuttle program was bound to get approved.
Even if the space shuttle program didn’t get approved, with the theory and technology of the Z-wave experiment, you can be sure that the next few decades will be a period of explosive growth in space technology. The industries related to space exploration will definitely experience significant development, and the market size is certain to expand explosively. Therefore, being at the top of the technology sector is very important.
Liu Jiankun had his reasons for being so proactive: for one, he is the CEO of Aviation Group, and the newly established company will certainly be a state-controlled holding; it is very likely to be directly under Aviation Group. The real moneymaking business of Aviation Group is actually in the secondary market, where income from the secondary market relates directly to the shareholders, while profits from other sectors have to be invested in various fields.
No matter how large that portion of income, it doesn’t have much to do with him personally.
Everyone has their own selfish interests.
Liu Jiankun, the CEO of Aviation Group and also a wealthy man, had a net worth exceeding two billion yuan.
This amount certainly couldn’t compare with Zhao Yi, but having achieved more than twenty "small goals," he was definitely among the richest.
In fact, Liu Jiankun and Zhao Yi were quite similar: for both, making money was an additional outcome, while their main focus was on managing companies and conducting scientific research—work contributing to the country’s strength and technological advancements, not being purely businessmen.
Nonetheless, everyone hopes to have more wealth in their hands.
If one can earn more money while doing their job, why wouldn’t they rejoice at the opportunity?
Thus, Liu Jiankun was very keen on the establishment of the new company because it was sure to be a subsidiary of Aviation Group—a company that could go public on its own and had great potential to stand at the forefront of the space exploration industry. Its future could be said to be limitless.
For such a company, the planning stage offers the best investment opportunity.
Zhao Yi didn’t pay much more attention. He only needed to wait for news, and he would need to take action once there were new developments.
The most important task now was to refine the theories of Z-waves and space based on the data and conclusions from the experiments.
Space analysis is the core of everything.
Through research on spatial barriers, anti-gravity, spatial shielding, spatial connection, and Z-waves, and based on the analysis of space, a significant part, even the main core theory, was almost complete, forming a closed loop. freewebnσvel.cøm
Of course.
This portion of the theory might not capture all the aspects of space, but the relationship between the external environment and particles, which can be scientifically and realistically perceived, had mostly been deciphered.
The content being added now filled the previous gaps in the theory, but there was still a certain distance from forming a complete theoretical loop.
Zhao Yi discovered that because the main core theory hadn’t yet formed a closed loop, even the experiments just completed couldn’t be fully explained.
One of the most critical points was the conservation of energy between space and particles.
During the large-scale Z-wave experiment, there was a conservation of energy issue.
Research on spatial barriers (anti-gravity) found that space passively absorbs energy.
Zhao Yi understood this to mean that space expands by absorbing energy, which in the context of the universe, led to the continuous expansion of the universe’s edge.
Z-wave energy, on the other hand, is anti-energy of space.
Anti-Energy is contrary to the energy absorbed by space. To be precise, in the large-scale Z-wave experiment, Z-wave energy wasn’t absorbed by space, but rather had a pure reactionary interaction with it, resulting in the compression of space. The effects of spatial compression on matter, whether it’s the magnetic fields that matter forms, the energy released by plasma state matter, or the direct compression of matter, are all results of spatial compression.
Spatial compression, when reflected in the universe, is akin to a direct reduction of a portion of cosmic space.
This is like taking a spoonful of water from the ocean; a spoonful of water is too insignificant to the ocean to cause any noticeable effect, but in reality, the ocean has indeed lost some water, and this lost part does have mass.
The ocean water has mass, and space can be understood as energy.
If space expands by absorbing energy, then the spatial void that disappears should theoretically convert into energy.
However, matter being compressed doesn’t increase mass—it seems to be just a physical compression, albeit at the particle level.
According to the conservation of mass-energy, the energy of matter hasn’t increased, but on the contrary, mass is slightly lost through radiation and heat generated in the process, which means there is an energy loss.
So where did the energy involved in the reaction go?
That’s the problem.
The energy seems to have disappeared out of thin air, and finding an explanation seems impossible.
Zhao Yi considered many possibilities, such as the compressed space converting into pure energy or into a magnetic field, but each was conclusively ruled out.
A magnetic field is just the expression of particles resisting spatial compression, and the heat and radiation from spatial compression reactions with matter can be detected; these only account for a very small portion of the reaction energy.
At this point, the conservation of mass-energy seemed invalid.
Zhao Yi wasn’t sure if the conservation of mass-energy was completely accurate, but he was absolutely certain that energy itself must be conserved.
Energy acts as an intermediary between particles and space.
Space can convert into energy, and particles can also convert into energy. Whether or not mass-energy conservation is absolute remains uncertain, but overall energy must be conserved, and energy cannot simply vanish into nothingness.
