A new study published in Nature demonstrates a significant breakthrough in quantum computing, achieving a record 99.9% fidelity in two-qubit gate operations using silicon spin qubits. This milestone, reached by researchers at a leading university, marks a critical step toward building scalable, fault-tolerant quantum computers. The team utilized a novel microwave-based control technique to manipulate …
A new study published in Nature demonstrates a significant breakthrough in quantum computing, achieving a record 99.9% fidelity in two-qubit gate operations using silicon spin qubits. This milestone, reached by researchers at a leading university, marks a critical step toward building scalable, fault-tolerant quantum computers. The team utilized a novel microwave-based control technique to manipulate electron spins with unprecedented precision, reducing error rates to a level previously thought unattainable with silicon-based systems. This advancement is particularly promising because it leverages manufacturing techniques compatible with existing semiconductor technology, potentially easing the path to large-scale quantum processor production. The research indicates that silicon, the backbone of classical computing, could also become a dominant platform for quantum computation. Read the full article at: https://sciencedaily.com/releases/2023/10/231005123456.htm
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