Researchers extend the lifetime of the qubit.

Image 1: Molecular qubit

Researchers extended the lifetime of the molecular qubits. Many things are making molecular qubits interesting tools in quantum computing. 

Researchers can create molecular qubits by putting some atoms (like krypton, helium, gold, etc.) in the fullerene molecule. Then they are driving information to that atom.

Then that atom sends the information to the fullerene core. And after that, the fullerene core will transmit the data to the multiple receiving sensors. If that system uses a C60 molecule. That allows the creation of a qubit that has 60 channels. 

Image 2: C60 Fullerene

Also, receivers have numbers. The system uses numbered data segments. So the data line will delete all other segments than the segment whose number matches the number of the data line. So when data arrives at line 5 the receiver destroys all other data segments than segment number 5. And that allows putting the data row into pieces. Then the system turns the data row into a line. 

The thing that makes qubit so important is that it is required in the process. That transforms the data row into the data line. Diagram 1. There is a possibility to create qubits with four states by using electric wires when the temperature is as low as possible. But the molecule-based qubits are more useful in biological microprocessors. 

Diagram 1: Qubit's principle. 

A =Data row 1

B= The level that transforms data from row to linear form. 

C= Datarow 2. Where the system returns linear data in a row. 

The biological qubits can also transfer data to neurons or microprocessors. Genetic engineering allows researchers can create bacteria or viruses that can operate as a qubit. 

Researchers are the first time manipulated data inside the DNA. And that allows the creation of artificial bacteria which can transfer information to neurons or microprocessors. The idea is that the DNA transfer will make bacteria able to send electric impulses. Then the data that is stored in the DNA will transfer to the receivers which can be axons of living neurons. Or they can be microprocessors. 

Image 3: AIDS-virus

Or the virus itself turns into a molecular qubit. If we are looking at the AIDS virus nothing denies that it could work as a qubit. The system requires a genome where data is loaded. Then the qubit virus will send electric signals to receivers that can be the living neuron. Or they can be microprocessors. 

Human brain neurotransmitters are molecular qubits. And molecular qubits can use for transmitting data between living neurons and non-organic microprocessors. There is a possibility that some viruses can transform into molecular qubits. DNA could be excellent data storage. And the outer core of the virus can send electric impulses to the receivers. 

The problem is how to make the internal data of the DNA transform electric signals. The answer can be simple. The retrovirus will infect the bacteria. And then that transforms the cell into a memory neuron. Or the DNA can turn the bacteria to be able to give electric shocks. Then the DNA would transfer its data by using those electric shocks as the transmitter. 

https://scitechdaily.com/quantum-breakthrough-scientists-extend-qubit-lifetimes/

https://scitechdaily.com/scientists-have-found-a-way-to-manipulate-digital-data-stored-in-dna/

https://en.wikipedia.org/wiki/Fullerene

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Image 1: https://scitechdaily.com/quantum-breakthrough-scientists-extend-qubit-lifetimes/

Image 2: https://en.wikipedia.org/wiki/Fullerene

Image 3: https://medizin.plus/krankheiten/hiv

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