Neutral atoms are less sensitive to electromagnetic fields than some ions. So electromagnetic fields don't affect the neutral atom's positions as much as they affect the ion's positions. And that thing brings room-temperature operating quantum computers closer than before. The use of neutral atoms to make quantum entanglements might happen by flashing them with laser rays.
That laser ray would electromagnetic shadow on the other side of the atoms. And then there is the possibility that electrons from electron shells can be locked in the line. When a laser ray stresses that atom. Those electrons act like an antenna that sends information in the wanted direction.
"QuEra Computing, creator of the world’s first neutral-atom quantum computer named Aquila, in collaboration with researchers from Harvard and Innsbruck Universities, has revealed a novel method for performing a broader range of optimization calculations on neutral-atom machines. The findings overcome the native connectivity limitations of the qubits in Rydberg atom arrays, enabling them to solve more complex optimization problems, including maximum independent sets on graphs with arbitrary connectivity and quadratic unconstrained binary optimization (QUBO) problems". (ScitechDaily.com/Encoding Breakthrough Unlocks New Potential in Neutral-Atom Quantum Computing)
"The additional functionality opens up applications in industries like logistics and pharmaceuticals, aiding in efficient logistics scheduling and optimized protein design, which can expedite drug development and potentially increase revenue for pharmaceutical companies". (ScitechDaily.com/Encoding Breakthrough Unlocks New Potential in Neutral-Atom Quantum Computing)
All atoms can turn to Rydberg atoms. And in most futuristic quantum computers electrons form superposition and entanglements in Rydberg atoms. So, Rydberg atoms can act as atom-size quantum computers. And if the iron atoms that hang in the graphene net will turn to Rydberg atoms, acting as atom-size quantum computers that thing allows to create multi-state quantum computers that are more powerful than ever before.
In that complicated model, electrons form quantum entanglements inside atoms. But superpositions and entanglements also form between atoms acting as quantum entanglements. Same way electromagnetic fields around atoms can form independent quantum states. And that kind of quantum system can have billions of states.
The smallest possible quantum computers are smaller than protons or neutrons. In those theoretical models. The system puts quarks inside protons and neutrons for superposition and entanglement.
The hypothetical "iron star" can act as a model of the solid quantum state computer. In that model, the system puts iron atoms in the same way in structure. In that structure, the iron atom's north pole is against other iron atoms' south pole. And the system makes that thing by using magnetic fields.
In that model, the iron atoms form chains in extremely low temperatures and a strong magnetic field. Then the electromagnetic rays will send information to that iron layer. There is the possibility that the iron atoms will lock in the graphene net. And laser rays will lock their electrons in the same direction. The graphene net will also send data to the transmitting side of those iron atoms. The data can put to jump back and forth between those graphene-iron layers.
When data is transferred from sender to receiver the system stores the information. Then the receiving side of the quantum entanglement will turn to the transmitting side. And the system can make that thing by changing the higher energy side on the quantum entanglement. Information always flows from the higher energy side to the lower energy side. And chancing the higher energy side in quantum entanglement is possible to adjust the information flow's direction in the system.
https://scitechdaily.com/encoding-breakthrough-unlocks-new-potential-in-neutral-atom-quantum-computing/
https://en.wikipedia.org/wiki/Iron_star
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