Cryo-CMOS for Quantum Computing
Edoardo Charbon (TU Delft - OLD QCD/Charbon Lab, École Polytechnique Fédérale de Lausanne, TU Delft - (OLD)Applied Quantum Architectures)
F Sebastiano (TU Delft - Electronic Instrumentation)
Andrei Vladimirescu (Institut Supérieur d’Electronique de Paris,, TU Delft - OLD QCD/Charbon Lab, University of California)
Harald Homulle (TU Delft - OLD QCD/Charbon Lab)
S. Visser (External organisation)
L Song (TU Delft - ImPhys/Quantitative Imaging, Tsinghua University)
R.M. Incandela (TU Delft - OLD QCD/Charbon Lab)
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Abstract
Cryogenic CMOS, or cryo-CMOS circuits and systems, are emerging in VLSI design for many applications, in primis quantum computing. Fault-tolerant quantum bits (qubits) in surface code configurations, one of the most accepted implementations in quantum computing, operate in deep sub-Kelvin regime and require scalable classical control circuits. In this paper we advocate the need for a new generation of deep-submicron CMOS circuits operating at deep-cryogenic temperatures to achieve the performance required in a fault-tolerant qubit system. We outline the challenges and limitations of operating CMOS in near-zero Kelvin regimes and we propose solutions. The paper concludes with several examples showing the suitability of integrating fault-tolerant.qubits with CMOS.
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