The famous double-slit experiment: But in this time rather, in time than space.

The famous double-slit experiment shows that light has a particle and wave nature. The research team of Royal London College made a new version of that experiment to demonstrate and investigate the light special relation to time. Time and light have a special relationship because of photons. That travels in the universe does not turn older. 

The reason is that time is stopped in the particle that travels with the speed of light.  And that is the thing that makes photons very interesting particles. When we think that the speed of light is a certain energy level, we can make photons travel back in time, by increasing it's energy level. Theoretically, this thing can open marvelous possibilities for quantum computing. 

What if researchers someday can bring information back from the future? Even if that thing is possible in a time limit that is less than a second, it allows to creation the backup qubit that the system sends to the future. And then the system can catch that qubit when it re-adjusts the quantum entanglement. The thing that makes quantum entanglement interact through time and space is one of the most interesting things in the world.

Quantum computers are the most powerful calculation machines that humans ever created. Their problem is that the system can keep quantum entanglements stable only in a couple of seconds or less than a minute. Normally, systems that create complicated models use alternative quantum- and binary systems where quantum computers send intermediate results for binary systems while they re-adjust themselves. 

"A team of international physicists led by Imperial College London has successfully recreated the double-slit experiment, demonstrating light’s dual nature as both a particle and a wave, but this time in the domain of time rather than space. The experiment relied on materials that change their optical properties in femtoseconds (quadrillionths of a second), which could potentially be used in new technologies or to explore fundamental questions in physics".(ScitechDaily.com/A Quantum Leap Through Time: Famous Double-Slit Experiment Reimagined)

"The researchers used a thin film of indium-tin-oxide, a metamaterial, which had its reflectance changed by lasers on ultrafast timescales, creating the ‘slits’ for light. This groundbreaking experiment could lead to the development of ultrafast, parallelized optical switches and pave the way for future research in time crystals and metamaterials".(ScitechDaily.com/A Quantum Leap Through Time: Famous Double-Slit Experiment Reimagined)

The quantum system uses artificial-intelligence-based adjustment tools, that take into account differences in the environment like radiation level, sun's activity, and in the future, gravitational waves. Also changes in electricity oscillation affect the quantum computer's ability to maintain the quantum entanglement. The number of variables determines how long the quantum system can keep the quantum entanglement, it's also possible that the system uses quantum systems alternatively. 

But the problem in both cases is that when the system sends information between quantum computers and the binary system it must encode that information from qubit to binary mode. And then, the system must encode binary data back from the binary model to the qubit. In that process, there is a possibility that something affects the qubit. And when the system transports information between two quantum systems it must throw qubits like balls. 

The problem is that. If some outside effect affects the qubit while it travels between systems that can turn the solution wrong. Even if the system uses two or double qubits. There is a possibility that the outside effect transforms those qubits. But if the system can send a qubit into the future and then catch the same qubit. It can make sure that data, stored in qubit has not changed. That thing, of course, requires that the qubits are not chancing while they are sent to the future and then catch again. 

The idea of the quantum system that sends information to the future and catches it again is interesting. The base of that system is in time dilation. The model of time is like a river or track. When energy impulse stops time in a particle time travels faster around it. That means the time dilates. And when the system removes energy from the particle time starts to travel faster around the object.

If the energy level of the particle is high its aging will slow. In slow energy levels in particles, time moves faster. Time is relative. That means when the energy level of another particle rises it starts to travel forward in time. Then another particle follows the first particle. The thing is that quantum entanglement is two particles that oscillate precisely with the same frequency. And it's possible to rise the energy level of another particle so high that it starts to travel forward in time. 

So, when the system inputs energy to a particle, it makes it travel to the future. And when it decreases the particle's energy level another part of the system will reach it. 

There is a possibility that the system will decrease the time in the particle. And then, it will stop it or even turn time travel backward in particles by using WARP bubbles. That thing makes it possible that the entirety that comes behind that particle catches it. 

https://scitechdaily.com/a-quantum-leap-through-time-famous-double-slit-experiment-reimagined/