Superposition, time, and quantum computers.

"A recent quantum computing breakthrough has enhanced the scalability and efficiency of quantum computations, moving closer to practical quantum computing advancements. Credit: SciTechDaily.com" (ScitechDaily, Quantum Computing Transformed by Breakthrough Photonic Technology)

All our wireless communication is based on superposition. The system puts two electromagnetic fields to oscillate at the same frequency. The reason that the radio transmitter will not turn into a qubit is that its field is not symmetrical enough. The thing, that we can call fluttering makes it impossible to create a quantum computer using a single radio transmitter.

A multichannel radio transmitter is the model of a quantum computer. There each frequency is one state of the qubit. The system shares data from data flow to all states of the qubit. That means the system turns data flow into data lines. And the thing that makes the quantum computer faster, is that it drives larger data bites from the bit flow forward. 

The problem with the qubit is this. When it's both sides reach the same energy level. That destroys the qubit. This is one of the reasons why researchers are working with primordial black hole theories. The primordial black hole allows to creation of smooth and powerful energy fields that can make it possible to create long-term qubits. And another thing is that the Kuiper belt is an excellent place for quantum computers. Stable and low energy conditions are good things for those powerful calculation systems. 

The knowledge of symmetry is essential for quantum computers. When researchers make things like qubits. They must understand and model the system's symmetry. And they must model that symmetry mathematically for quantum computers. This makes some symmetry formulas very important for researchers. Symmetries in qubits are important. The key element in the qubit is superposition. The quantum system makes two particles oscillate at the same frequency. 

"A novel quantum entangled optical atomic clock at CU Boulder offers groundbreaking precision in timekeeping, opening new avenues for quantum technologies and precision measurements, albeit with limited operational duration. Credit: SciTechDaily.com" (ScitechDaily, Timekeeping Innovation: Quantum Entanglement Unlocks Unprecedented Precision)

The other, transmitting part of the superposition must be at a higher energy level than the receiving part. And when those parts are at the same energy level, the standing wave between those particles destroys the qubit. This makes it hard to make error detection protocols for quantum computers. In regular computers, the system just makes those calculations backward. If the result differs from the original values there is an error. Another way is to use two or more computers to make the same calculations. 

It's possible to make two or more quantum computers to make the same calculations. But quantum computers are sensitive to things like cosmic radiation and other effects that are meaningless to binary computers. Things like solar flares and changes in Earth's magnetic, and gravity fields cause problems with qubits. And those large-scale effects might remain unseen because they affect all quantum systems at the same time. 

This is why making the calculations backward is important. But the problem is that if the quantum computer wants to make this thing it must drive information into another quantum computer because it cannot turn that qubit around. When the system re-adjusts the qubit, the system must turn the receiving part of the qubit into a higher position. And that must go through the position, where the energy levels of qubit are the same.  

"A  University of Science and Technology of China, USTC-led team achieved the first loophole-free test of Hardy’s paradox, confirming quantum nonlocality and closing key loopholes. Their findings have important implications for quantum technology development. Credit: SciTechDaily.com" (ScitechDaily, Hardy’s Paradox Finally Confirmed: Landmark Experiment Shakes Local Realism)

Another problem with quantum computers is that the receiving part of the qubit doesn't just pull all the energy that it receives into it. The energy or information travels through the receiving part's quantum field causing a flash. Or it causes a rise in energy levels around the receiving part of the qubit. That thing destroys the qubit. Some researchers call that thing a "three-effect problem". The third effect is the thing that destroys the qubit. That third effect is heat. But things like gravity waves may have more effect on qubits than people even think. 

"A Rutgers professor, Pham Tiep, has cracked two major mathematical puzzles, advancing our understanding of symmetries and random processes in numerous scientific fields, ranging from chemistry and physics to engineering, computer science, and economics. Credit: SciTechDaily.com" (ScitechDaily, Rutgers Professor Cracks Two of Mathematics’ Greatest Mysteries)

This is why researching things like atom clocks is important. The problem with atom clocks is that they need radioactive components.  In the wrong hands, those components are dangerous. There have been attempts to use things like neutron star pulsars to replace the radioactive atom clocks. 

The other way to make effective atom clocks is to use a black hole's oscillation and its gravity waves or changes in radiation levels for time measurements. The gravity waves could act as time signals if their distance is stable. The gravity wave sends a signal to the gravity wave detector, that can use those gravity waves as a time signal. However, the requirement is that the distance or frequency of those gravity waves is stable. 

Researchers can observe anomalies in those system's operations. And then they can see if there is some kind of effect in the qubits. The new quantum entanglement-based atom clocks can be more effective than the old ones. 

Normally researchers use things like stopped photons to make the qubits. Those photon pairs will be put into superposition and entanglement. The system takes photons into the frame and stops them. Then the electromagnetic system creates the qubit. Maybe in the future, quantum computers use diamonds where the system stops photons in the diamonds, or maybe it will use the phonons as acoustic qubits. 

https://scitechdaily.com/hardys-paradox-finally-confirmed-landmark-experiment-shakes-local-realism/

https://scitechdaily.com/quantum-computing-transformed-by-breakthrough-photonic-technology/

https://scitechdaily.com/rutgers-professor-cracks-two-of-mathematics-greatest-mysteries/

https://scitechdaily.com/timekeeping-innovation-quantum-entanglement-unlocks-unprecedented-precision/