How to use quantum entanglement in long-range communication?

There are two ways to use that spooky effect of distance in long-range communication. The first one is to use quantum entanglement itself. In that case, the superpositioned and entangled particles would pull to long distances. As I wrote before the quantum entanglement between superpositioned particles is like a stick. When another side of that particle pair moves another one is also moving.

Another way is to make the superposition and entanglement and shoot laser rays through that thing. In that case, the superposition is made vertically through the laser ray, and that thing is making possible to adjust the energy level of the laser ray. Making the superposition and entanglement is a little bit more conventional way to make communication than the first way.

The idea of the vertically superpositioned and entangled particles is that only part of the laser ray is carrying information. That thing is a good way to protect the message from unauthorized access. The idea is similar to the laser rays that are traveling internally. The outer laser ray protects another laser ray. That travels inside it.

The core laser helps to detect if somebody wants to eavesdrop on the message. If somebody wants to detect the information that travels in the internal laser. The catching system disturbs the core laser and that is visible in the control room.

If long-range communication is possible by using quantum entanglement itself. That is the revolution for information transport. If somebody disturbs quantum entanglement that is visible immediately.

If we want to make the superposition and entanglement between two particles. Where another is at Alpha Centauri. That thing requires so high an energy level that we cannot make that thing yet. But if we could make that superpositioned and entangled particle pair and send another part of that thing to Alpha Centauri. That thing makes it possible to create a quantum communication tool that allows long-range communication in real-time.

https://miraclesofthequantumworld.blogspot.com/

Comments

The LK-99 could be a fundamental advance even if it cannot reach superconductivity in 400K.

The next step in superconducting research is that LK-99 was not superconducting at room temperature. Or was it? The thing is that there is needed more research about that material. And even if it couldn't reach superconductivity in 400K that doesn't mean that material is not fundamental. And if LK-99 can maintain its superconductivity in 400K that means a fundamental breakthrough in superconducting technology. The LK-99 can be hype or it can be the real thing. The thing is, anyway, that high-voltage cables and our electric networks are not turning superconducting before next summer. But if we can change the electric network to superconducting by using some reasonable material. That thing can be the next step in the environment. Superconductors decrease the need to produce electricity. But today cooling systems that need lots of energy are the thing that turn superconductors that need low temperatures non-practical for everyday use. When the project begins there is lots of ent

Black holes, the speed of light, and gravitational background are things that are connecting the universe.

Black holes, the speed of light, and gravitational background are things that are connecting the universe. Black holes and gravitational waves: is black hole's singularity at so high energy level that energy travels in one direction in the form of a gravitational wave. We normally say that black holes do not send radiation. And we are wrong. Black holes send gravitational waves. Gravitational waves are wave movement or radiation. And that means the black holes are bright gravitational objects. If we can use water to illustrate the gravitational interaction we can say that gravitational waves push the surface tension out from the gravitational center. Then the other quantum fields push particles or objects into a black hole. The gravitational waves push energy out from the objects. And then the energy or quantum fields behind that object push them into the gravitational center. The elementary particles are quantum fields or whisk-looking structures. If the gravitational wave is

The ability to make single photons is vital for quantum computers.

The ability to make single photons is vital for quantum computers. Controlling complex systems requires that system operators have complete knowledge of the system and its interactions. The problem with error correlation in quantum computers is that the qubits and quantum systems are much more sensitive to outside effects than binary computers. The other problem is that the anomaly that causes a calculation error can also happen during the second calculation. Things like gravity waves are global anomalies that affect all quantum computers. And that thing means that all quantum computers can calculate wrong at the same moment. The big problem is also that quantum computers are the only things that can check and find errors in another quantum computer's solutions. Binary computers make the same 45-year calculations that quantum computers can make in seconds. And that thing means that outside things like torrents of gravity waves can destroy all the results that the Quantum systems pr

Cogito ergo sum. I think; therefore I am (René Descartes, French philosopher)

Search This Blog