"The diamond quantum chip used in this research. Credit: QuTech" (ScitechDaily, Quantum Computing Breakthrough Achieved With Diamond Qubits)
"Scientists at QuTech have achieved a major milestone in quantum computing by creating highly precise quantum gates on a diamond chip, hitting error rates as low as 0.001%." (ScitechDaily, Quantum Computing Breakthrough Achieved With Diamond Qubits)
"By using ultra-pure diamonds and advanced gate designs, the team overcame key challenges that have limited previous approaches. These precise gates passed rigorous testing with long sequences of operations, marking a significant step toward building scalable quantum computers." (ScitechDaily, Quantum Computing Breakthrough Achieved With Diamond Qubits)
The problem with quantum computers is the gate that controls the information flow. The qubit can involve at the same time multiple zeros and ones. When the quantum computer loads information to qubits we can think this thing is similar to the cases where the system spray paints that information to the qubit. But in that case, the system makes the 3D structure like a globe. There the mountains and hills are the zeros and ones.
Diamond qubits make quantum computers more effective. The prime question in those systems is how to stabilize that qubit. The qubit makes quantum entanglement between two photons. And then, it starts to make data transmission between those photons. Another promising thing to make qubits is neutrons. Neutrons are bipolar particles with N/S polarity. And that makes those particles capable of operating as qubits.
The system transmits information into the neutron's quantum field. That energy pike in the spin axle should transmit it forward.
The problem is that the neutron is not slight enough. The main problem is to control the photon. And transmit data in it. It's possible to use diamonds. Or, nanodiamonds trap photons and then transmit information between those diamonds. In some other cases, the nanodiamonds can also use phonons to transmit information in the quantum computer.
The nanodiamonds and phonons are tools. That can make so-called acoustic qubits possible. The acoustic qubits are like quantum organs. In that system, all nanodiamond pairs have different resonance frequencies. So each of those pairs has different impurities and different colors.
The acoustic or phononic qubits can mimic human brains. The idea is that those nano-size diamonds act like neurons.
One of the reasons. Why human brains are so effective is that those neurons are close to each other.
In the same way. In acoustic quantum computers, those diamonds are close to each other. And they can be closed in the nanotubes. That protects the acoustic transmission. The system is like the radio-wave-based systems. There each radio frequency is one layer or state of the qubit. Those diamonds can also send information in the form of EM radiation.
Those diamonds are in opposite graphene networks. Nanodiamonds are precisely opposite to each other. A laser beam forms the phonon into those diamonds. And then. That phonon transmits data between those layers and nanodiamonds. This is one vision of acoustic qubits.
The acoustic qubit means. That there the atoms or some atomic or subatomic particles like protons and neutrons that move.
There is the possibility. The acoustic qubit sends the proton or some other particle to the quantum channel. That particle can also carry data itself. In that model, the acoustic system just kicks the qubit forward.
https://scitechdaily.com/quantum-computing-breakthrough-achieved-with-diamond-qubits/
https://en.wikipedia.org/wiki/Phonon
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