Quantum entanglement is one of the most useful things in quantum mechanics.

This is writing about data transportation by using quantum entanglement. There is also the possibility to use quantum entanglement in particle accelerators and advanced ion engines. But I will write about those things later. 

When we look for practical solutions for quantum mechanics we must look at quantum entanglement. Quantum entanglement or the spooky effect in distance means. That the elementary particles are at the same time in two places. That happens by putting those elementary particles oscillating with the same frequency.

The thing that makes information travel in the quantum computer is that another side of the quantum entanglement is at a higher energy level than the other. That thing causes the information flows to the side of the quantum entanglement. That is at the lower energy level.

And when the sides of the quantum entanglement are at the same level. That thing causes the radiation or wave motion that those particles send brake the quantum entanglement. And that thing is one of the most interesting things if we want to transport information long distances in the form of a qubit.

At this point, we must make a difference between long-distance and short-distance quantum communication. Of course, there is no theoretical limit to the length of quantum entanglement. But transporting qubit long distances can happen quite a simple way. 

In qubit-based quantum communication, the information would load to the quantum entanglement. And then the quantum entanglement's energy level will put the same level. Then the wave motion will push those participants of that thing away from each other. 

If quantum entanglement is made by using the particles that react with magnetic fields. That thing makes it possible to aim those particles away from each other. Then the particle that transports information can put to travel in the hollow laser or microwave ray. That thing protects the electron or positron that transports information. 

This is the reason why things like positronium are under research. Positronium is the system where electrons and positrons (anti-electrons) orbit each other. If quantum superposition is made between electron and positron. 

That thing allows the creation of superposition that the system can easily control by using magnetic fields. Also if the transporter particle in long-distance quantum communication is the positron. That makes it easy to destroy it after the data. That improves data security.

Destroying data transporter by using annihilation denies the attacker's ability to steal them. After the data transporter traveled through the sensor there is a theoretical possibility that somebody could steal it. And then that attacker could restore the data remnants but that thing is purely a theoretical way to steal information from the quantum system. 

See also: Positronium

Electrons are acting like tsunamis in the superconducting wires.

The researchers of the University of Tampere have discovered the new thing in the superconducting world. Electrons are traveling in the superconducting cable like tsunami waves. And that thing can bring new visions in the world of quantum physics and quantum mechanics. 

When electron swarms are traveling like tsunamis they have a very large capacity to transmit data. And that thing can use to send data to quantum computers. If the electrons are transmitting data to the quantum computers are moving in the form of a fan. Every each electron can shoot to its layer or state at the same time. So that thing can make the electron-tsunamis an interesting tool in computing. 

The electron tsunamis are the thing that can use for modeling the hypothetical wormhole or Einstein-Rose bridge. The slowing of the particles crushes them. Not travel through the energy channel. 

The idea of the wormhole is that the wave movement is traveling in the energy channel in one direction. That means that the time is slowing in the wormhole. So the electron tsunami has caused an idea that the information will be crushed when it comes out from the wormhole. The idea is easy to explain when we are using tsunamis as an example. 

If we are riding with tsunami at the open sea that thing is not dangerous. The danger is that when the tsunami hits the beach that thing causes the situation when we are flying to the sand. So the thing that causes damages and breaks our bones is the slowing. Riding with electron tsunami in the wormhole is safe until we come out from that thing. 

The quantum fields will crush the information when they are coming out from that energy channel. The thing that is making the wormhole so an effective transportation system, if it exists is that there are no quantum fields. That means nothing will slow the particle in the energy tunnel. When the particle comes out from that energy channel it hits the quantum field of the regular universe. That quantum field slows the particle. And slowing the speed is crushing the information. 

Even if we cannot create a wormhole between two black holes. We can probably make the virtual wormhole in extremely cold conditions. In the virtual wormhole, the wormhole is made by using a laser ray. Then the electron tsunami is launched in it. And the probe will travel in the electron cloud and laser ray to distant objects. But the virtual wormholes can use in quantum computers for protecting the data transportation in quantum computers. 

But maybe someday in the future...

The electron tsunami can put to travel in the laser ray. That is used as the virtual wormhole. But maybe in the future, the large-size laser can be used to create the virtual wormhole for the probes that are using an antimatter engine. The large, nuclear-powered laser can position in the Kuiper belt. 

And then the probe can shoot to the Alpha Centauri inside the laser ray and it can ride by electron tsunami. The Voyager-size probe that has an antimatter rocket could travel long distances in space inside the laser ray. And the electron cloud can put to travel within the laser channel. The idea is that the laser channel or virtual wormhole can protect the data transmission between the probe and its senders. 

https://www.tuni.fi/en/news/electrons-behave-tsunamis-findings-hold-promise-discovery-new-superconductors

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

Image: https://upload.wikimedia.org/wikipedia/commons/5/55/Large_breaking_wave.jpg

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