"Physicists have successfully identified and manipulated a specific thorium atomic nucleus state using a laser. This discovery enables the merging of classical quantum physics and nuclear physics, promising advancements in precision measurement technologies and fundamental physics, including the potential development of a nuclear clock surpassing current atomic clocks in accuracy. A laser beam hits thorium nuclei, embedded in a crystal. Credit: TU Wien" (ScitechDaily, Decades in the Making: Laser Excites Atomic Nucleus in Groundbreaking Discovery)
During a groundbreaking study, researchers manipulated a single thorium atom's nucleus. The ability to manipulate atoms and their nucleus allows the system to store data in those atoms.
If the system can have the ability to store and transmit data between atoms and in their electrons can used in the next-generation quantum processor. The ability to write and read data into atoms requires. The system can measure differences in the energy levels in those particles.
If the system can turn two opposite atoms into a quantum computer. It requires the ability to store data in the atom's nucleus. The system can make superpositions and entanglements between electrons that orbit the atom's nucleus in the 2D layer.
When we think of the quantum computer it's possible to create a system that looks like a CCD camera. The number of activated photoelectric points determines the qubit's state. The next-generation mass memories can store information in quantum dots. The multiferroic nanodots can act as data storage.
The system can look like a chessboard or QR code, and the data that the system stores into those dots. Can be driven into the quantum computer in the quantum state. The system can share data to quantum states using those dots.
When those quantum dots are opposite to each other. That thing makes it possible to transport data between those quantum dots in their entirety. The system shares information between those quantum dots.
And then it just transports all information as an entirety. When we think of the system that should recover or collect data from the hard disks, the system must only measure differences in the voltage on the surface of that hard disk. Then operating. The system transforms those differences in voltage level into ones and zeros.
More accurate systems that react with different voltage levels can determine the qubit's state. We can think that the qubit is like an onion and the system transports data from A to B it just sends one layer from sender (A) to receiver (B).
The new groundbreaking crystal freezes photons in time.
What would you do with frozen photons? Those photons can store data in the photonic form. In that case, the quantum system data can transfer data into those photons. And then the system can put them into the superposition and entanglement. Those frozen photons can also used to measure things like gravity waves. When gravity waves hit those photons, that affects their annealing or their energy level.
That makes it possible to create a system, that can revolutionize the measurement. When some system transports information from the system, it simply measures the differences in the energy levels of the data tool. When the system can see those changes in the chemical or quantum field structure, that thing makes it possible to drive data between mass memory and the processor or qubit.
https://scitechdaily.com/decades-in-the-making-laser-excites-atomic-nucleus-in-groundbreaking-discovery/
https://scitechdaily.com/photons-frozen-in-time-by-innovative-crystal-designs/
https://scitechdaily.com/revolutionizing-memory-tech-the-rise-of-low-power-multiferroic-nanodots/
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