The best outco would be for the device to operate continuously without interruption.
If a problem arises halfway through, the experint will have to be stopped for modifications and adjustnts, and then preparations for a second trial can begin.
Fortunately, since nuclear fusion is not nuclear fission, the fusion reaction is quite comprehensive. There’s no high radioactivity partway through, and with the isolation effect of the space casing, there’s virtually no radiation outside the device, so it won’t produce a large amount of unmanageable waste.
As long as the core of the device doesn’t have any problems, as long as the seal is maintained, the only thing that needs to be dealt with is the insufficiently reacted raw material.
The nuclear fusion device uses deuterium-tritium fuel and carries out the ’first generation’ of fusion reactions.
’First generation’ fusion reactions definitely can’t match ’deuterium-helium-3’ or ’helium-3-helium-3’ reactions, but the advantage lies in the low cost of the raw materials, so the cost-effectiveness is very high. Additionally, control is sowhat easier.
"If a larger spacecraft needs to be built, requiring higher power output, then the ’second generation’ or ’third generation’ of fusion reactions could be considered," Zhao Yi explained to the others regarding internal reaction issues.
Another cost of terminating an experint is the ignition issue, as initiating nuclear fusion is extrely difficult. Each ignition requires a significant expense.
Luckily, the advent of Z-wave ignition technology has greatly reduced the difficulty and cost of ignition, thereby significantly reducing the loss incurred by stopping an experint.
——
Five days later, the experint officially began.
The preparation ti for this experint was still quite long, at least that’s how Zhao Yi saw it. Considering the difficulty and importance of controlling nuclear fusion, he found the lengthy preparation acceptable.
When the preparations for the experint officially started, everyone was very tense and excited.
Most of the experintal group, including the visiting delegation, stayed away from the device.
During the process of conducting a nuclear reaction experint, the risk is still very high. Even data monitoring is done remotely, and only a small control group remains near the experintal device.
Those who are not directly involved can’t see what’s happening inside the experint; what they can see from the outside includes the operation of large power pumps and the electrical power output that’s being tested.
The electrical power output paraters are crucial.
The electrical power output paraters tested are the external output power of the nuclear fusion device.
For the nuclear fusion device to maintain operation and external power output is key because the nuclear fusion itself must power the anti-gravity device, as well as other auxiliary devices and electronic systems, all of which rely on the power produced by the fusion reaction.
It is after deducting the power consud by these that the external power output can be determined.
Once the experint officially started, many people kept their eyes on the power output paraters.
After about fifteen minutes or so, the needle on the power output detection instrunt finally moved slightly, a small motion that excited everyone.
"It’s a success, we have data!"
"This is truly remarkable, look, the power pumps are starting to operate as well."
"Indeed, can we now say that the experint has been a success?"
"We’ve made history, controlled nuclear fusion, achieved!"
"Although we were ntally prepared, this is still so exciting, absolutely amazing! We’ve succeeded!"
Success, as ntioned by everyone, ans that the nuclear fusion device successfully produced external output power. Having external output power signifies the success of the nuclear fusion device. Even if the output power was only 1 watt, it would still be an important milestone.
Clearly.
The overall external output power of the device couldn’t possibly be just 1W; the internal reaction had to beco more and more intense, and the output power kept increasing. In about half an hour, it rapidly climbed to half the estimated maximum figure.
At that point, everyone beca even more excited.
If the device’s external output power could reach the predicted figures, and run continuously without any major issues, it would indicate that the device could be used to manufacture spacecraft.
Even with the current output power, it would be sufficient to serve as a small nuclear power plant, and considering the cost of extracting raw materials, the electricity generated over ti would far exceed the cost.
Now it could be said that the experint was a success.
However, everyone still kept their eyes on the needle of the power output detection instrunt, because the anticipated maximum power was twice the current amount.
Only with a power output double the current level could it support the operation of a large spacecraft.
The purpose of the current nuclear fusion experint, of course, is not just to build a nuclear power station, but most importantly, to support spacecraft.
If the power output failed to et expectations, one could say the experint was only half successful.
But, what followed was sowhat disappointing.
The needle on the power output detection instrunt did not continue to rise, but remained in place for a long ti. This suggested that the maximum power was around here and wouldn’t rise further.
"Has the reaction reached its most intense state now?"
"The output power is insufficient!"
"Why is it so much less than expected? There must be a problem sowhere!"
Everyone knew there was a problem because the expected figures were significantly higher, but making corrections was extrely difficult.
Firstly, the problem had to be identified, and to do so, the experint had to be stopped.
This caused a dilemma for the experintal team.
Many people didn’t know whether to be happy or discouraged—happy because the experint was partially successful, indicating that controlled nuclear fusion was achievable, but discouraged because the power output had not t expectations. Perhaps a second or even a third experint would be needed to truly succeed.
At that mont, Zhao Yi examined the detector’s gauge and furrowed his brow in deep thought.
He suddenly said, "I’ll go have a closer look. We can’t make out anything from here."
"No way!"
A senior leader imdiately objected, "That’s too dangerous."
"Academician Zhao, you mustn’t go near the device, it’s far too risky."
"Yes, Academician Zhao, safety is the most important thing!"
"The experint has been very successful; as long as we identify the problem, next ti we will definitely succeed."
"Don’t take the risk!"
Despite everyone’s attempts to dissuade him, Zhao Yi shook his head and said, "We don’t know how long we’ll have to wait for next ti. I have confidence in my own design; it should be safe."
"Besides, there’s already a working group inside. Our safety is important, but so is theirs. If they’re not afraid of the dangers, what are we afraid of?"
He insisted on going over.
Realizing they couldn’t dissuade him, soone finally bit the bullet and said, "Academician Zhao, I’ll go with you."
"I’m coming too. What’s there to be afraid of; it’s only life after all!"
"Exactly!"
"I trust Academician Zhao’s judgnt; we’ll find the problem if we’re up close!"
In the end, the group went over.
About twenty people, including a senior leader, went to the experintal working group together.
The location of the working group was only about twenty ters away from the experintal device. If there was any leakage or other issues with the device, there was a high probability it would affect the area where the working group was located.
If the experintal device encountered a major problem, such as a strong explosion, it would cover the surrounding area up to one kiloter, with severe effects within ten kiloters.
Even a minor error in the experint could be fatal.
Everyone was aware of the danger, and people kept discouraging the group from approaching the work area as they made their way there.
However, Zhao Yi insisted on going. He wasn’t worried about the danger, as "Law of Cause and Effect" had very effective safety controls.
If a real danger arose, they would be forewarned and able to evacuate quickly.
So Zhao Yi remained very calm, even to the point of seeming completely indifferent to his own life, a deanor that earned others’ admiration.
"Academician Zhao truly is deserving of respect. Such a spirit of sacrifice is incomparable!"
"For the success of the experint, Academician Zhao isn’t afraid to sacrifice! But we must ensure his safety; he is too important!"
"We can afford to sacrifice, but Academician Zhao must be safe!"
Amidst ongoing anxiety, the group finally approached the experintal device and arrived at the working group’s location.
This was the best place to check the data.
The working group operated various detection equipnt, constantly ready for the device’s operation status. The people working inside were completely surprised to see the leaders’ group co in.
"This is too dangerous!"
"This place isn’t safe! Why did you all co?" In the midst of constant exclamation and concern, Zhao Yi entered calmly and started examining the detailed detection data.
His composure alard people, as if unconcerned with safety issues at all, which made the others, apprehensive about the situation, continue to exclaim in admiration, "Academician Zhao is truly remarkable!"
"To ensure the success of the experint, he’s even willing to risk his life!"
"It’s just so, so, so—"
"Grand!"
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