The gravity role in the micro-universe is bigger than physicists have expected.

.

The gravity role in the micro-universe is bigger than physicists have expected. 

Normally the minimum errors that gravity makes for the interaction between particles like single atoms are meanless. But that interaction might have a large role if even the smallest interaction would affect in the same direction even millenniums. That thing can cause changes in the form of the interplanetary nebulae, and this will affect every particle in the universe. 

But there is one thing, where we should notice the gravity effect. That thing is the nano- and quantum technology. In those extremely small structures, the smallest possible effects can cause, that the things like atoms or subatomic particles are going to the wrong direction or in the wrong place in the extremely small structures. 

If we are thinking about the large-scale nanotechnical structures, what is forming about the atomic chains or the extremely small weakly interactive particles like entangled photons the things like gravity waves can break the structure. In those cases, the small effect, that hits to particle constellation from the unexpected side can cause that the structure will be broken. And this thing makes also the minimum gravitational effect very important. 

The proton and electron pillars between the graphene layer can operate as the new type of qubits. 

Can we someday make the structures, which are made just by using only electrons? In that kind of structure, the gravity can operate as glue, which keeps those things in the form. Those kinds of things can be used as qubits. If that kind of structure of homogeneous polarity particles like electrons or ions can be formed that thing can make them the new type of qubits. If we are thinking that this kind of structure is made by using protons or some other positive ions we model that thing as the pillar between graphene layers. The positive ions can pull electrons to them. 

Theoretically adjusting the electricity level of those pillars is easy. If we are shooting electrons to that pillar it would decrease the capacity. And increasing the capacity of this type of qubit can make by shooting it with laser rays. But the problem is how to connect the same polarity ions in the entirety? Maybe the answer can be found from fermion or boson stars. The question is how those strange stars are staying in one piece? If we find the answer, that can make the new type of qubits and more effective quantum computers possible. 

The minimum gravity effect makes things like a boson, and fermion stars possible. The thing that makes fermion stars possible would be that the electrons have different gravity fields, and in some cases, the gravity field of the electrons can be more powerful than the electromagnetic pulling force between those particles. So the gravity will make it possible to connect the particles that have similar electric polarity. 

If we are thinking possible to make the structure that is created by just electrons the gravity effect between those particles will be very small. But it would be acting like glue. The idea is that the mass of some electrons is increased by using a laser, and that thing makes the electrons that are stressed by using the electromagnetic radiation heavier than others. So it can make it possible to make structures, that are made only by using electrons. 

https://www.sciencealert.com/gravity-could-be-more-important-on-the-smallest-scales-than-physicists-thought

https://www.sciencealert.com/there-could-be-transparent-stars-made-of-bosons-masquerading-as-black-holes

https://ui.adsabs.harvard.edu/abs/1999CoTPh..32..457J/abstract

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

Image: https://nineplanets.org/gravitational-force/