Translator:
Henyee Translations
Editor:
Henyee Translations
This laboratory was an âinvestmentâ under the Max Planck Institute for Plasma Physics. Obviously, many other research institutes around the globe were also researching the same device.
Lu Zhou looked at the list of cooperating research institutes; the list of names was long enough to fill an entire A4 page. If this was like CERN, where everyone involved had their name on the final thesis, then the first few pages of the thesis would be filled with just names.
The stellarator seemed small compared to the research group.
Lu Zhou and Professor Klitzing followed Professor Keriberâs footsteps. They finally walked into the radiation protected room and saw the Wendelstein 7-X.
It sat quietly in the middle of the radiation protected room; it was 3.5 meters high and 16 meters wide. The stellarator looked like the âMillennium Falconâ from Star Wars.
It was like it had just been in a battle and was docked in the âStar Harborâ while it was being fixed by technicians.
Lu Zhou walked closer and could see countless electric cables connecting to various types of equipment. It was all tangled together.
âHow much is this thing?â
âApparently, itâs over one billion euros,â Professor Klitzing said with admiration. âIf you add in the cost of research, the figure would be astronomical.â
The physics community was envious of the funding that the Institute for Plasma Physics had.
On the other hand, the Max Planck Institute for Condensed Matter Physics had a lot less funding.
Klitzing was well aware of this.
After all, this multi-country collaborative project wasnât only funded by Germany, many other countries also participated.
âIs it really that expensive?â
Lu Zhou gulped.
Before this, he was wondering if he should buy one for research, but now, it seemed that it would be better if he stuck to supercomputers...
âFine, who cares about money, we donât have to worry about that,â Professor Keriber said as he patted Lu Zhouâs shoulder. He then added, âThe final calibrations are done, the experiment is about to start, letâs go to the observation room.â
...
This was different than CERN. The Hadron Collider was 100 meters underground, and unless someone was a qualified engineer, they would not be able to enter the pipeline.
The theoretical physicists could only look at data on a computer screen.
But now, the Stellarator was right in front of Lu Zhouâs eyes.
The staff members were waiting inside the observation room.
âCoil tension normal!â
âFilling in protective gas!â
âProtective gas is filled, beginning pressure measurement procedure!â
â...â
âSuperconducting temperature reached, the circuit is fully charged!â
âMagnetic field looks normal!â
Professor Keriber issued a command.
âIgnite!â
The moment the magnet current reached 15kA, the thyristor switches quickly switched on and the magnet current was transferred to the first stage energy-consuming resistor, generating 2,400 voltage. This caused the gas in the vacuum chamber to break down, thereby generating plasma.
Lu Zhou could see a layer of reddish membrane material through the screen; it formed a ring around the circular orbit.
He was surprised at how beautiful it was.
â... The temperature of the plasma will reach hundreds of millions of degrees at its peak. Almost equivalent to the center of a star. No material can stop this energy,â Professor Klitzing said while he looked at the screen.
Lu Zhou asked, âHow does the stellarator do it?â
âIt twists the magnetic field.â Professor Klitzing said, âWe use magnetic fields to constrain the energy, and it keeps them away from the inner walls of the orbit. However, it doesnât last for long...â
The experiment entered the most critical stage.
The thyristor switched turned off, and the voltage dropped to 1000V. At the same time, the current rose to its peak value, and the entire track was filled with burning light. Lu Zhou felt that his eyes were hurting even though he was looking at it through a screen.
However, this light didnât last for long.
Within a few seconds, the light had vanished.
The stellarator stopped operating, but the people in the observation room began working.
Professor Keriber told his two researchers, âCollect the data immediately, check the condition of the equipment, hurry!â
At the same time, the door of the radiation protected room opened, and staff members wearing radiation protection suits quickly entered the room with several tools. They began to check the physical conditions of the track.
Lu Zhou looked at Professor Keriber and asked, âItâs over?â
âItâs over.â Professor Keriber threw his hard hat on the table and said, âThe discharge time was a few seconds, the longest I can remember is six seconds. The shortest is only a few picoseconds.â
Lu Zhou was speechless.
â... I thought it would be more astonishing.â
Professor Keriber smiled and said, âTheoretically, the discharge time can be longer, but right now, the divertor hasnât been installed. The excessive discharge might cause the head to damage the first wall of materials. Maybe in two years, once the water-cooled divertor has been installed, a 30-minute discharge might be possible.â
The discharge timed referred to the time in which the magnetic field could maintain a charge, the so-called pulse time of one discharge.
30 minutes was a goal for the Wendelstein 7-X.
If it were achievable, it would have a huge impact on the nuclear fusion project. It might even change the entire worldâs opinion on nuclear fusion engineering.
After all, right now the mainstream choice was the tokamak, but the tokamak reached a bottleneck in terms of its discharge time.
The longest discharged time recorded was Chinaâs âEASTâ tokamak, with a record of 102 seconds. This was almost at the limit of the tokamakâs capabilities.
Lu Zhou looked at the device and began to think.
Suddenly, he had a thought.
How much general points would the system charge for a complete stellarator blueprint?