Operating semiconductor quantum processors with hopping spins

Qubits that can be efficiently controlled are pivotal in the development of scalable quantum hardware. Resonant control is commonly embraced to execute high-fidelity quantum gates but demands integration of high-frequency oscillating signals and results in qubit crosstalk and heating. Establishing quantum control based on discrete signals could therefore result in a paradigm shift. This may be accomplished with single-spin semiconductor qubits, if one can engineer hopping spins between quantum dots with site-dependent spin quantization axis. Here, we introduce hopping-based universal quantum logic and obtain single-qubit gate fidelities of 99.97 99.992 that have been predicted to allow for quantum error correction. We demonstrate that hopping spins also constitute an elegant tuning method by statistically mapping the coherence of a 10-quantum dot system. These results motivate dense quantum dot arrays with sparse occupation for efficient and high-connectivity qubit registers.