论文信息 - 19.2 A 110mK 295µW 28nm FDSOI CMOS Quantum Integrated Circuit with a 2.8GHz Excitation and nA Current Sensing of an On-Chip Double Quantum Dot

19.2 A 110mK 295µW 28nm FDSOI CMOS Quantum Integrated Circuit with a 2.8GHz Excitation and nA Current Sensing of an On-Chip Double Quantum Dot

To reach quantum supremacy, quantum computers need >50 logical qubits with <mv accurate biasing, GHz-range signal handling, and µs readout of thousands of physical qubits at sub-Kelvin temperatures. Silicon-based qubits are a promising approach to scale the qubit number owing to their low footprint (100nm) and gaining from the CMOS industrial background to reach maturity [1]. Moreover, the quantum silicon choice allows the IC community to integrate large-scale qubit-control electronics directly nearby the quantum silicon core, thus drastically reducing the wire-connection number and qubit-addressing fanout, meanwhile increasing the operation bandwidth for error correction and the spin-readout sensitivity.

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