Quantum physicists are teleported "qutrits" for the first time.

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Qutrits are giving superpowers for a quantum system.

Qutrits are giving superpowers for a quantum system. In the most conventional case, the data is transported in the form of qutrit. But if the computer or quantum computer starts to use a ternary system that makes them even faster than they are. The ternary system allows making the virtual layers inside every state of the qubit.

Qutrit or quantum trit is the cubit equivalent of a triangular number system, the ternary system. A trit is the bit equivalent in a ternary system. And that means if the quantum computer uses qutrits their power will increase. 

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The qutrit(1) can give extreme power to quantum computers. 

The qutrit means that the quantum computer uses the ternary numeric system in each layer(2). That will give the quantum computer extreme power in data handling. 

Normal quantum computers use qubits where the data is packed in many layers. The idea is that the system transmits data by using many layers at the same time. But each layer is using a binary system. 

This means that a qubit-based quantum computer is only the group of binary computers that are cutting their mission in the pieces. And share it with many machines. 

But if the system uses qutrits each layer of the quantum system uses the qutrits the system uses a ternary system. And the ternary system allows making the system that uses virtual qubits. 

A binary system means that a number comes after one. So in the natural binary system used numbers are 1 and 10.  Natural ternary system the system uses numbers 1,2, and 10. In numeric systems, the number ten is the changer.

In a computer, binary numeric system markings are 0 and 1. 

Zero means the gate is closed. 

Number 1 means that electricity or data is traveling in the system. That means the system has two states: on and off. 

In computers, ternary system markings are (0,1,2). The ternary system will make computing faster. The third number allows using so-called stop-bit. In that version, the ternary system uses number 2 as the separator between data lines. 

But there is a more powerful method in the ternary computing system. And that is that the system will send the data to the upper layer or share it with internal qubits in the layer. In that kind of system, the qutrit is acting as the virtual qubit in each layer of the quantum computer. 

In the computer ternary numeric system, the system uses three numbers (0,1,2). That thing makes it possible to use the third determinator in programming. In a binary system, the gate is open or it is closed.  

Or the router can be in two positions and select route one or route two. The ternary system allows that the router can route data by using three routes. Or the gate can also transfer data to the upper level. 

That means when the state of the ternary system gets 0 or 1. The system acts like a normal computer. But if the value is three the system sends the data to the upper level. 

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Diagrams of the ternary system: (https://en.wikipedia.org/wiki/Ternary_numeral_system)

The idea is that there are qubits or qutrits in two chambers. Then the oscillation of those qubits would synchronize by using those bottles or chambers. The idea is that those qutrits or qubits are made in quantum fog inside those chambers. 

Long-term data transmission through the air between two quantum systems is needed radio transmitter. As an example, the five-layer qubit requires five radio frequencies. The system will send data for each layer of a qubit by using those frequencies at the same time. And each qubit layer has its own radiofrequency.

There is the possibility to transmit data through the air in long distances between quantum computers by using radio waves quite easily. In that system every, layer of the qubit has its radiofrequency. So in the five-layer qubit, the system uses five radio frequencies for transmitting the data between qubits. 

The data will send through the air by using radio transmitters. And then the receiving part will drive that data to the qubit. The skyrmions might be suitable for driving the data in the qubit. 

Then that annealing will transfer to the chamber and send to another chamber. If those chambers are identical the oscillation will transfer to the quantum fog. In another version, the qubits will superposition through the air from the first chamber to another. 

The difference between the second and the first case is in the direction where the oscillation comes. In the first case, the energy for annealing the particles will mean that the reaction in chamber 1. Which is transmitting chamber will get the oscillation frequency from inside out. 

And the second chamber that is receiving chamber will send the oscillation wave movement from the outside to inside. And in the second version, the superposition will create straight between the quantum fog inside chambers. That chamber is needed for driving data to the radio transmitters. 

https://phys.org/news/2019-08-complex-quantum-teleportation.html

https://www.thespaceacademy.org/2021/10/quantum-physicists-have-teleported.html?m=1

(1)https://en.wikipedia.org/wiki/Qutrit

(2)https://en.wikipedia.org/wiki/Ternary_numeral_system

Image I:https://www.sciencenews.org/article/quantum-physicists-teleported-qutrits-first-time

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