When the quantum computers come out from the shadows?

One of the things that are limiting the quantum computer's turn more common is the infrastructure that doesn't fully support them.  The advantage of the quantum internet goes the same path as the advantage of the regular internet. And one of the bottlenecks is that the normal binary-based internet cannot transport data in the form of the qubit. 

The speed of the binary mode data transportation is the bottleneck of the system. The binary-based data transportation protocol is not so fast that it fully supports the quantum computer. In the hybrid system, the data is loaded to the door server. And that thing is resending data to the quantum computer.

The things like quantum teleportation and particle-wave duality where the light is turned to electron and positron are the things that can solve the data transportation problem. In that system, the qubit is formed in the channel of the quantum processor by shooting the laser light to the channel where is moving high energetic photon quantum. 

The positron can also use as a qubit. And when the data is loaded that qubit can annihilate and that makes the ultimate data security. But the problem is the radiation. 

When the quantum computers come out from the shadows? That's a good question. When quantum computers are turning common there will be commercial solutions. And that thing will increase the speed of the development of quantum computers. Investments in that technology make it easier to develop new advantages for those systems. 

The fact is that the perfect computers require the infrastructure that supports the use of those systems. The use of quantum computers will happen through the gate computers over the internet. And that means theoretically those systems can use remotely by using existing technology. 

The only need is to make contact with the gate computer, and then send the data to a quantum computer through the internet. But because the data is not transported as qubits. And it must transform to the qubit model before the quantum computer can handle it. Makes the system slow. So the power of the quantum computer vanishes in the network infrastructure. 

Another thing is that quantum computers are vulnerable to particle radiation. If electron or beta radiation or some ion hits the qubit that thing is a catastrophe. The thing is that if we want to get the full benefit from the quantum systems. We must make infrastructure that fully supports the communication between quantum computers by using qubits as the data transporters. 

The problem is in the long-range data transportation in the qubit form. In electromagnetic radiation, each wavelength can be the independent state of the qubit. And if the system uses radio waves or multi-channel radio, every channel can be the layer of the qubit.  Of course, things like electrons can shoot inside the laser rays that are protecting the data carrier. 

We can replace regular electric cables by using nanotechnical particle accelerators that can carry electrons or protons inside them. Or we can send data by using light cables. The different color of laser rays is the different wavelengths of light. 

So turning regular data to the different wavelengths of light allows turning laser rays into qubits that can carry the data in the qubit form. The same way the radio waves can use as the long-range qubit. By sharing data with multiple bandwidths of the radio at the same time. This thing allows creating the data transporter that carries data in multiple layers at the same time. 

()https://en.wikipedia.org/wiki/Wave%E2%80%93particle_duality

()https://en.wikipedia.org/wiki/Qubit

()https://visionsoftheaiandfuture.blogspot.com/