Two-qubit logic and teleportation with mobile spin qubits in silicon
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The scalability and power of quantum computing architectures depend critically on high-fidelity operations and robust and flexible qubit connectivity. In this respect, mobile qubits are particularly attractive as they enable dynamic and reconfigurable qubit arrays. This approach allows quantum processors to adapt their connectivity patterns during operation, implement different quantum error correction codes on the same hardware, and optimize resource utilization through dedicated functional zones for specific operations like measurement or entanglement generation. Such flexibility also relieves architectural constraints, as recently demonstrated in atomic systems based on trapped ions and neutral atoms manipulated with optical tweezers. In solid-state platforms, highly coherent shuttling of electron spins was recently reported. A key outstanding question is whether it may be possible to perform quantum gates directly on the mobile spins. In this work, we demonstrate two-qubit operations between two electron spins carried towards each other in separate traveling potential minima in a semiconductor device. We find that the interaction strength is highly tunable by their spatial separation, achieving an average two-qubit gate fidelity of about 99\%. Additionally, we implement conditional post-selected quantum state teleportation between spatially separated qubits with an average gate fidelity of 87\%, showcasing the potential of mobile spin qubits for non-local quantum information processing. We expect that operations on mobile qubits will become a universal feature of future large-scale semiconductor quantum processors.
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