WELCOME

In the early stages of the fusion reactions, the atoms

May 29, 2019 by Ella Pickett

In the early stages of the fusion reactions, the atoms would have a high concentration of electrons and charge that could be separated. But eventually, the atoms would be trapped so that the free electrons can't be made to travel beyond the plasma. When that happens, the atoms would be made to move on their own and will eventually get separated from the plasma.

As we talked about in our last post, these experiments have been performed in the lab of physicists from Germany and the United Kingdom.

And that's where the good stuff comes in. One of the things that gives positrons their unique look and feel is that the atoms are in a relatively constant state of discharges. If they were trapped within the plasma, they would be able to escape that discharges easily. This means that they're much safer.

This research was done with a pair of plasma-releasing accelerators that were placed in a fusion reactor at Ohio State University. The two accelerators were used to perform a test on plasma-releasing accelerators that were placed in a fusion reactor at Ohio State University.

And that was just one experiment. If the accelerators failed, the plasma could get trapped. But if the accelerators succeeded in trapping the plasma and allowing it to escape, you were safe to expect that the plasma would eventually get separated from the plasma. So these accelerators did the job and so you were safe.

That's just one example of what we did to make positron-conducting plasma in the laboratory. But it's just one demonstration. What we have shown here is that for a high-energy, extremely low-energy (HV) plasma, the plasma will escape if the magnetic field is not strong enough to trap it.

The experiment also used a device called a 'photon accelerator'—a kind of 'transmitter' that can measure the energy of a plasma. It wasn't intended as an experiment—it was to help people understand the phenomenon of magnetic fields that can form in plasma. And that's how they did it.

But they also used these accelerators to test the effect on the plasma. One of the advantages of these accelerators was that they could measure the magnetic field of a plasma. So they could measure it while it was still in the air.

At the fusion reactor where this experiment was performed, the plasma was in a constant state of discharges that had been measured before—about three times the normal concentration of electrons and charged. The plasma was able to escape from that dis