The hypothetical zero-energy point of the universe: all electrons and gluons are frozen, and even the movement of subatomic particles ends.

Above this text is an image of Boomerang nebula. The coolest place outside the laboratory which temperature is 1Kelvin (Wikipedia/Absolute zero)

The Bose-Einstein condensate is the extremely low energetic atom which electrons are in minimum energetic orbitals. But could somewhere in the universe be the condition where all movements including movements of gluons and electrons end? Could that hypothetical condition cause the situation that the electrons would drop to the nucleus of an atom?

In that case, the energy level of the atom would be dropped so low. That the electrons are frozen. The idea for that thing is coming from the visible effect when the temperature of the material is decreasing the oscillation of the material is decreasing. At the first stops the oscillation of molecules, then the oscillation of the atoms stops. So could the chain of that oscillation of the material continue that the movement of electrons would end? And could the oscillation of gluons end inside the protons and neutrons?

So the minimum energy level of material means that all movement inside atoms and subatomic particles like protons and neutrons ends. When the movement of electrons and gluons ends, that thing means that all movement is ending. And the temperature cannot turn lower. So if we are calling the point where helium freezes as absolute zero degrees of kelvin or simply zero-kelvin or absolute zero. At that point, electrons are orbiting nuclei of atoms. So the atomic oscillation ends. But the movement of subatomic particles like electrons and gluons continues.

There is the possibility that by decreasing temperature or energy level from zero kelvin degrees we could reach the point, where the movement of electrons and gluons is ended. We can call the point where electrons and gluons are stopped absolute zero point of energy. Theoretically, there is the possibility to reach that energy minimum. But making that thing in practice is a different thing.

While the temperature or energy level of an object decreases. The speed of the decreasing temperature is also slowing. And reaching that mythic zero-energy point of material would take an extremely long time.

The thing that makes the low-energetic areas in the universe interesting is that energy can form for nothing. There must be some kind of particles that are forming the wave movement that turns to the material. So if we can imagine the situation where the "bubble of nothingness" would be formed by pulling the quantum field around the proton outside.

There is the possibility that the energy flow from the dark matter will start to fill that absolute empty area where is no other quantum fields or energy. This is the thing that makes the minimum energy level interesting.

What if the energy in the particles turns lower than the minimum energy level of the universe would be? There is the possibility that these kinds of particles would start to conduct the energy from the dark matter to the visible material. The thing that makes that kind of thing interesting. And the same way difficult to understand. Is that we don't know anything about the minimum energy level of the universe.

We know that the oscillation of the atoms is ending in zero kelvin temperature. But the movement of the electrons continues. So there must be a temperature where even electrons are not moving. But reaching that level of energy is extremely difficult. The idea of decreasing temperature is a simple thing. The energy would transfer from one point to another.

So the energy cannot just disappear. It can only travel from one point to another. There must be something that conducts energy away from particles. And that thing makes it difficult to make the conditions. Where even the subatomic particles like electrons would freeze.

In that case, the energy layer of the atoms is pumped so low. That those electrons that orbit the nucleus drop to the surface of the nucleus of the atom.

But creating that hypothetical temperature is extremely difficult because that thing requires that the movement of the electrons ends. And nobody has reached that temperature yet.

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

There is a suggestion that dark matter may have deformed another universe.

The researchers suggest that dark matter is the deformed dark universe. Or in the most exciting theories, dark matter is the dark universe inside our universe. In that theory dark matter is entangled with the visible material. That theory is taken from the multiverse theory. There our visible universe is one of many universes. The other universes can be invisible because their electrons and quarks are different sizes. And that thing makes those other universes invisible to us. Another hypothesis is that the hypothetical other universes send radiation that radiation from our universe pushes away. Things like invisible 9th. planet causes ideas that maybe there is another universe in our universe. The thing that makes the mysterious dark matter interesting is that. The dark matter can form structures that can be similar to visible material. But those structures are not visible. The multiverse theory is not new. The thing in that theory is that there are multiple universes at this moment

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Nano-acoustic systems make new types of acoustic observation systems possible.

' Acoustic diamonds are a new tool in acoustics. Another way to make very accurate soundwaves is to take a frame of 2D materials like graphene square there is a hole. And then electrons or laser beams can make that structure resonate. Another way is to use the electromagnetic field that resonates with the frame and turns electromagnetic energy into an oscillation in the frame. Nano-acoustic systems can be the next tool for researching the human body. The new sound-wave-based systems make it possible to see individual cells. Those soundwave-based systems or nano-sonars are tools that can have bigger accuracy. Than ever before. The nano-sonar can use nanodiamonds or nanotubes as so-called nano-LRAD systems that send coherent sound waves to the target. In nanotube-based systems, the nanotube can be in the nanodiamond. The term acoustic diamond means a diamond whose system oscillates. The system can create oscillation sending acoustic or electromagnetic waves to the diamond. Diamond

Visions of bright future

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