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Asteroids' heavy secret.

   Asteroids' heavy secret. 


Superheavy elements can exist on asteroids. Researchers calculated that the elements with around 164 protons and the same number of neutrons can be stable. If that kind of stable but extremely heavy element or isotope is possible to find, that thing could revolutionize space travel. Superheavy elements allow them to make small but powerful nuclear reactors. In some visions, those reactors are like balls. And then laser rays will make time dilation in them. 

The lasers will press that ball where there are some superheavy elements. But the problem is, how to make those systems create more energy than they use. That is not important on spacecraft where the purpose of those systems is to transport spacecraft between point A and point B. In spacecraft, the energy can stored in fuel, and production requires a lot of energy. But in commercial solutions that efficiency is urgent. 


"Scientists have been creating superheavy elements and believe elements with around 164 protons might be stable. Determining their density is crucial, with asteroids being potential reservoirs. Space missions are underway to analyze asteroid samples for these elements." (ScitechDaily.com/Scientists have been creating superheavy elements and believe elements with around 164 protons might be stable. Determining their density is crucial, with asteroids being potential reservoirs. Space missions are underway to analyze asteroid samples for these elements.)



"The heaviest element on the periodic table has 118 protons". (ScitechDaily.com/Scientists have been creating superheavy elements and believe elements with around 164 protons might be stable. Determining their density is crucial, with asteroids being potential reservoirs. Space missions are underway to analyze asteroid samples for these elements.)


Producing that kind of element by using particle accelerators is possible. But if researchers can find those superheavy elements on an asteroid, where solar wind acts like a particle accelerator that makes it possible to create those superheavy particles with lower costs. The thing where researchers need those superheavy elements is in a miniature nuclear reactor. 

The miniature nuclear reactors give the small-size shuttles and aircraft new abilities like the ability to patrol at the same time space and atmosphere. But the small nuclear reactors must have fuel. One version of those super powerful reactors can be the particle accelerator where the super heavy noble gas element 118 orbits. The element 118 named "Oganesson" has an extremely short period of decay. 

But by using extremely low temperatures along with time dilation where that element is stored in a particle accelerator could be possible to turn element 118 into fission fuel. That superheavy element's speed would be as fast as it can, and that thing causes time dilation that makes this element's existence so long, that it can be used in a fission reactor. The diagram where laser ray travels through asteroid could be the system that produces the superheavy elements. The idea is that the laser ray acts like a thermal pump that pulls plasma through the asteroid. 

And that process turns the ions and asteroid particles into that superheavy element that is not confirmed yet. In some visions, the laser ray that travels under the spacecraft's floor could also used to create artificial cravitation. The electromagnetic thermal pump pulls quantum fields to the floor and then aims them in a certain direction. And that effect forms the artificial gravitation also for the non-rotating spacecraft. 

https://scitechdaily.com/from-alchemists-to-astrophysicists-do-asteroids-hide-superheavy-secrets/

https://en.wikipedia.org/wiki/Oganesson

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