Cryo-CMOS Circuits and Systems for Scalable Quantum Computing
E. Charbon-Iwasaki-Charbon (TU Delft - (OLD)Applied Quantum Architectures, Intel Corporation, TU Delft - OLD QCD/Charbon Lab, École Polytechnique Fédérale de Lausanne)
F. Sebastiano (TU Delft - Electronic Instrumentation)
M. Babaie (TU Delft - Electronics)
A. Vladimirescu (University of California, Institut Supérieur d’Electronique de Paris,)
M. Shahmohammadi (TU Delft - Electronic Components, Technology and Materials)
R.B. Staszewski (TU Delft - Electronics)
H.A.R. Homulle (TU Delft - OLD QCD/Charbon Lab)
B Patra (TU Delft - OLD QCD/Charbon Lab)
Jeroen van Dijk (TU Delft - (OLD)Applied Quantum Architectures, TU Delft - OLD QCD/Charbon Lab)
R.M. Incandela (TU Delft - OLD QCD/Charbon Lab)
Lin Song (Tsinghua University)
Bahador Valizadehpasha (Student TU Delft)
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Abstract
Quantum computing holds the promise to achieve unprecedented computation power and to solve problems today intractable. State-of-the-art quantum processors consist of arrays of quantum bits (qubits) operating at a very low base temperature, typically a few tens of mK, as shown in Fig. 15.5.1 The qubit states degrade naturally after a certain time, upon loss of quantum coherence. For proper operation, an error-correcting loop must be implemented by a classical controller, which, in addition of handling execution of a quantum algorithm, reads the qubit state and performs the required corrections. However, while few qubits (∼10) in today's quantum processors can be easily connected to a room-temperature controller, it appears extremely challenging, if not impossible, to manage the thousands of qubits required in practical quantum algorithms [1].
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