The new type of fusion reactor is ready for ignition.

The new in this kind of fusion system is that the energy is transferred to the gold bites in the form of high-energetic laser rays. Those gold bites are turning the laser rays into the X-rays, which are targeted to the fusion fuel in the middle of the system. The fusion system uses the quantum annealing principle, where the quants around the system area are stressed with energy. This kind of fusion system can use as the base for making X-ray lasers.

The problem with a fusion reactor is that the pressure and ignition energy must point to the fusion fuel in absolutely symmetric form. If there are anomalies in the ball, the plasma would behave in an unexpecting way. This kind of fusion reactor which is seen above this text can be like a tube where the fusion material is traveling through the fusion system in a straight tube. The pressure and ignition lasers affect plasma symmetrically, and the distance between the wall and the fusion material is the same from all sides.

Because fusion fuel is coming in the middle of the fusion chamber. That reaction is easier to control than the donut-type reactor. The fuel can deliver in the middle of the reactor. And the used fusion fuel can conduct away from the reactor more easily than in the donut-type reactor.

In the center of the system is put the X-ray source, and then the other X-ray sources are put around that X-ray. The system could work with the normal cathode tubes, but this kind of high-energetic system can make the more powerful laser rays. The nuclear explosion-base X-ray lasers can create by shooting the laser ray through the tunnel across the nuclear explosive. And then the nuclear detonation will increase the power of the X-ray systems.

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