Electromagnetic fields could explain the origin of the FRBs.

 Electromagnetic fields could explain the origin of the FRBs. 

Researchers found disturbing electromagnetic fields near the point where the FRBs (Fast-Radio Busts) are coming. And maybe those electromagnetic fields can explain why the origin of the FRB is so hard to determine. The origin of electromagnetic fields is electromagnetic radiation. And electromagnetic radiation can form the magnetic lens as well as gravitational waves form a gravitational lens. 

The powerful magnetic field can create an electromagnetic lens that will target the electromagnetic radiation at one point. An electromagnetic field can pull the ions together. And that thing can form spontaneous fusion. The plus-pole field can pull anions together. 

Gravitational lensing can cause also increase the electromagnetic field's force by pulling particles into one position. If the gravitational lens is strong enough that thing can form a black hole, if it's big and strong enough. Same way, the gravitational waves can combine their power with radio waves. Electromagnetic fields are also interacting with radiowaves by changing their course.  

"Twisted fields around a mysterious fast radio burst. An international team has made significant progress in understanding the origins of Fast Radio Bursts (FRBs) – some of the most intense millisecond-duration cosmic explosions in radio bands. Credit: Di LI/ScienceApe/CAS" (ScitechDaily.com/Extreme Twisted Magnetic Fields Discovered Around Mysterious Fast Radio Burst)

So maybe the spontaneous fusion in the molecular nebula can explain why we cannot see the origin of the FRB. 

Electromagnetic fields can cause a thermonuclear explosion. There is a possibility that electromagnetic fields can press ionized material like gravitation. And if the magnetic field is strong enough that thing can pull hydrogen ions together. That thing could form a so-called spontaneous fusion. The electromagnetic field that creates fusion should be extremely strong, but maybe neutron stars can form an electron beam that pulls protons together. 

On a neutron star, strong gravitation can form the situation that a fusion reaction starts on its shell. But there is the possibility that the electron beam that leaves from the neutron star forms fusion in the place, where is no visible stars. 

Kilonovas or impacting neutron stars can form the electromagnetic shockwave that turns the interplanetary nebula around them to gold. And that thing forms nuclear fusion. The white dwarf can also pull lithium and hydrogen into its shell, and then the electromagnetic impulse that comes from the objects like black holes and neutron stars can cause fusion on the white dwarf's shell. 

"Artist’s impression of helium-rich material from a companion star accreting onto a white dwarf. Before the explosion, a large amount of material is stripped from the companion. The research team hopes to clarify the relationship between the emitted strong radio waves and this stripped material. Credit: Adam Makarenko/W. M. Keck Observatory" (Svitechdaily.com/Radio Signal Reveals Origin of a Thermonuclear Supernova Explosion)

In theoretical cold fusion, the laser beam is replaced by using strong magnets. The problem is how to make magnets that are strong enough that they can form nuclear fusion. 

Cold fusion can mean that the extremely strong magnetic field pulls particles together. And if that magnetic field is strong enough, it can make the ions and anions melt together. Theoretically, just magnetic fields can use to create fusion. In those cases, magnetic fields are just pressing ions or anions against a layer. In that case, the system would not need ignition lasers if those magnets are so powerful that they can melt ions or anions together. Making that system is hard because they require incredibly powerful magnets. 

If the high-power magnetic field can ignite fusion that thing can make new models of how the fusion system can ignite. If there is a highly magnetic stick inside the fusion chamber where the system injects the plasma, that thing makes the fusion easier to begin. The magnetic field will pull the plasma to the stick. 

And then, the ignition laser will ignite that material. The problem is that the magnetic field must be extremely strong that it can pull plasma to a plaque on the layer, where the laser ignites that thing. But theoretically fusion reactor could use an extremely strong magnetic field to ignite the fusion. Theoretically, a magnetic field that is strong enough can melt the ions or anions together. But it's hard to create a magnet that is strong enough.  

https://scitechdaily.com/extreme-twisted-magnetic-fields-discovered-around-mysterious-fast-radio-burst/

https://scitechdaily.com/radio-signal-reveals-origin-of-a-thermonuclear-supernova-explosion/