Cryogenic CMOS Interfaces for Quantum Devices

Conference paper (2017)

Authors

F. Sebastiano (OLD)Applied Quantum Architectures

J.P.G. van Dijk OLD QCD/Charbon Lab

Harald Homulle OLD QCD/Charbon Lab

R.M. Incandela OLD QCD/Charbon Lab

B Patra OLD QCD/Charbon Lab

M. Mehrpoo OLD QCD/Charbon Lab

M. Babaie Electronics -

A. Vladimirescu University of California, Institut Supérieur d’Electronique de Paris,

E. Charbon-Iwasaki-Charbon Intel Labs, OLD QCD/Charbon Lab , (OLD)Applied Quantum Architectures , Swiss Federal Institute of Technology

Research Group

(OLD)Applied Quantum Architectures

Quantum computing CMOS Cryogenics Qubits Cryo-CMOS

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Published Date

2017

Language

English

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Research Group

(OLD)Applied Quantum Architectures

Abstract

Quantum computers could efficiently solve problems that are intractable by today's computers, thus offering the possibility to radically change entire industries and revolutionize our lives. A quantum computer comprises a quantum processor operating at cryogenic temperature and an electronic interface for its control, which is currently implemented at room temperature for the few qubits available today. However, this approach becomes impractical as the number of qubits grows towards the tens of thousands required for complex quantum algorithms with practical applications. We propose an electronic interface for sensing and controlling qubits operating at cryogenic temperature implemented in standard CMOS.

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