"Artistic illustration showing the radio pulses emitted by the binary star system: a white dwarf in orbit around a red dwarf. Credit: Daniëlle Futselaar/artsource.nl" (ScitechDaily, Mysterious Space Signals Went Unexplained for Years – Astronomers Just Found the Star System Behind Them)
The binary star the red dwarf orbits the white dwarf is behind the mysterious long-period transients, LPT. The LPT signal is similar to a fast radio burst, FRB. But it has less energy. And it lasts longer. Now the white dwarf is the reason for that kind of radio burst that lasts in minutes. A white dwarf is a remnant of a solar-type star. Its gravity and magnetic fields are weaker than neutron stars.
The magnetic field around that star remnant is forming of the plasma interaction. The plasma that rotates around the white dwarf creates a magnetic field around that planet-size but more massive object. The dwarf planet Quaoar forms its magnetic field similar way. And that magnetic field forms a system around that dwarf planet in the Kuiper belt.
If Quaoar were closer to the Sun. That ring system would not exist because the solar wind blows those bites away. In that case, the weak magnetic field that plasma forms around Quaoar can trap those particles around it only because the solar wind is so weak.
This kind of phenomenon is possible. Only in stable conditions at the edge of the solar system. We cannot make models about asteroids and their rings using the same models all the time. In an asteroid belt, that kind of ring system is not possible. Asteroids can have rings in the very far away from the Sun.
A similar effect can be possible around neutron stars. In those cases, the effect is much more powerful than around dwarf planet Quaoar because neutron stars' gravity is more powerful than Quaoars weak gravity.
For a long time, researchers have wondered why objects that must be solid and dead have an extremely strong magnetic field. The answer can be in the plasma around the object. The plasma whirls around the object. In that case, the plasma acts as a rotor. And the object itself acts as the stator.
There is the possibility. In neutron stars. The neutrons that spin in the same direction participate in the magnetic field's formation. Lightweight neutron stars also have things like "neutron liquid" between their core and shell. That thing makes the strong endemic magnetic field that surrounds the magnetars.
But it's possible. Heavy neutron stars may not involve that "neutron liquid". The neutron liquid viscosity is the same as iron. The structure of that material is pure neutrons. Those neutrons act like quantum balls in ball seas. And that makes the neutron star's shell move faster or in another direction than the neutron star's core.
Those neutrons form the quantum rolls that make magnetar's extremely powerful magnetic field possible. In magnetar, the plasma and internal structure form the double field that breaks any records in the power of those fields. The outside energy pushes those neutrons on its shell into the neutron net or neutron lattice.
Heavy neutron stars might not have that neutron liquid. The lack of neutron liquid makes the heavy neutron star's structure solid. So, that means the heavy neutron star's magnetic field forms similarly. As dwarf planet Qauaoar magnetic field. There is exotic quark material inside the neutron stars. We can think that this exotic material is like powder, that cannot move those neutrons. The quark material's particle size is too small. That neutron shell cannot freely orbit around it. And gravity pushes that shell against the quark material.
The whirling plasma around the structure creates the plasma generator. In a plasma generator, the plasma pike forms the plasma axle or stator. And plasma whirls around it. Form a structure, that acts as a generator.
That causes questions about those heavy neutron stars. That is: can the neutron star exist without a magnetic field? If a neutron star with a solid structure is in a cosmic bubble that causes a situation that the plasma generator around it is gone. But then if that happens pressure against that structure ends. And it can explode neutron stars.
Asteroid, or dwarf planet Quaoar shows that the plasma whirls around the object can have the same effect as Earth's core. The black hole's magnetic field forms also in the same way as Quaoar's magnetic field. That dwarf planet is too small that it can have a liquid core. The plasma that its weak gravity traps forms a magnetic field that traps very small particles around them.
Same way. A black hole's only known interaction is gravitational.
If we think of the interactions with black holes themselves. The plasma around the black hole forms its magnetic field.
Magnetic fields accelerate particles inside them. When a red dwarf faces a white dwarf's magnetic field it causes interaction where particles from the red dwarf impact with particles in white dwarfs magnetic fields. That causes a very strong energy release. Those energy releases are always similar. But their strength and length can be different.
https://www.helsinki.fi/en/news/mathematics-and-science/finnish-researchers-have-discovered-new-type-matter-inside-neutron-stars
https://sciencesprings.wordpress.com/2024/01/04/from-the-university-of-helsinki-helsingin-yliopisto-fi-via-phys-org-further-evidence-for-quark-matter-cores-in-massive-neutron-stars/
https://scitechdaily.com/mysterious-space-signals-went-unexplained-for-years-astronomers-just-found-the-star-system-behind-them/
https://scitechdaily.com/space-mystery-unexpected-new-ring-system-discovered-in-our-own-solar-system/
https://en.wikipedia.org/wiki/Neutron_star
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