Cryogenic CMOS Interfaces for Quantum Devices

Fabio Sebastiano; Jeroen P.G. van Dijk; Harald A.R. Homulle; Rosario M. Incandela; Bishnu Patra; Mohammadreza Mehrpoo; Masoud Babaie; Andrei Vladimirescu; Edoardo Charbon

doi:10.1109/IWASI.2017.7974215

Cryogenic CMOS Interfaces for Quantum Devices

Fabio Sebastiano, Jeroen P.G. van Dijk, Harald A.R. Homulle, Rosario M. Incandela, Bishnu Patra, Mohammadreza Mehrpoo, Masoud Babaie, Andrei Vladimirescu, Edoardo Charbon

Electronics

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

21 Citations (Scopus)

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.

Original language	English
Title of host publication	Proceedings - 2017 7th International Workshop on Advances in Sensors and Interfaces, IWASI 2017
Place of Publication	Danvers, MA
Publisher	IEEE
Pages	59-62
Number of pages	4
ISBN (Electronic)	978-1-5090-6707-7
DOIs	https://doi.org/10.1109/IWASI.2017.7974215
Publication status	Published - 2017
Event	IWASI 2017: 7th IEEE International Workshop on Advances in Sensors and Interfaces - Vieste, Italy Duration: 15 Jun 2017 → 16 Jun 2017 Conference number: 7 http://iwasi2017.poliba.it/

Workshop

Workshop	IWASI 2017
Country/Territory	Italy
City	Vieste
Period	15/06/17 → 16/06/17
Internet address	http://iwasi2017.poliba.it/

Keywords

CMOS
cryo-CMOS
cryogenics
quantum computing
qubits

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10.1109/IWASI.2017.7974215

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Sebastiano, F., van Dijk, J. P. G., Homulle, H. A. R., Incandela, R. M., Patra, B., Mehrpoo, M., Babaie, M., Vladimirescu, A., & Charbon, E. (2017). Cryogenic CMOS Interfaces for Quantum Devices. In Proceedings - 2017 7th International Workshop on Advances in Sensors and Interfaces, IWASI 2017 (pp. 59-62). Article 7974215 IEEE. https://doi.org/10.1109/IWASI.2017.7974215

@inproceedings{c592f6f7c2bc49649428cead75cec2ab,

title = "Cryogenic CMOS Interfaces for Quantum Devices",

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.",

keywords = "CMOS, cryo-CMOS, cryogenics, quantum computing, qubits",

author = "Fabio Sebastiano and {van Dijk}, {Jeroen P.G.} and Homulle, {Harald A.R.} and Incandela, {Rosario M.} and Bishnu Patra and Mohammadreza Mehrpoo and Masoud Babaie and Andrei Vladimirescu and Edoardo Charbon",

year = "2017",

doi = "10.1109/IWASI.2017.7974215",

language = "English",

pages = "59--62",

booktitle = "Proceedings - 2017 7th International Workshop on Advances in Sensors and Interfaces, IWASI 2017",

publisher = "IEEE",

address = "United States",

note = "IWASI 2017 : 7th IEEE International Workshop on Advances in Sensors and Interfaces ; Conference date: 15-06-2017 Through 16-06-2017",

url = "http://iwasi2017.poliba.it/",

}

Sebastiano, F, van Dijk, JPG, Homulle, HAR, Incandela, RM, Patra, B, Mehrpoo, M, Babaie, M , Vladimirescu, A & Charbon, E 2017, Cryogenic CMOS Interfaces for Quantum Devices. in Proceedings - 2017 7th International Workshop on Advances in Sensors and Interfaces, IWASI 2017., 7974215, IEEE, Danvers, MA, pp. 59-62, IWASI 2017, Vieste, Italy, 15/06/17. https://doi.org/10.1109/IWASI.2017.7974215

Cryogenic CMOS Interfaces for Quantum Devices. / Sebastiano, Fabio; van Dijk, Jeroen P.G.; Homulle, Harald A.R. et al.
Proceedings - 2017 7th International Workshop on Advances in Sensors and Interfaces, IWASI 2017. Danvers, MA: IEEE, 2017. p. 59-62 7974215.

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

TY - GEN

T1 - Cryogenic CMOS Interfaces for Quantum Devices

AU - Sebastiano, Fabio

AU - van Dijk, Jeroen P.G.

AU - Homulle, Harald A.R.

AU - Incandela, Rosario M.

AU - Patra, Bishnu

AU - Mehrpoo, Mohammadreza

AU - Babaie, Masoud

AU - Vladimirescu, Andrei

AU - Charbon, Edoardo

N1 - Conference code: 7

PY - 2017

Y1 - 2017

N2 - 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.

AB - 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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KW - cryo-CMOS

KW - cryogenics

KW - quantum computing

KW - qubits

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BT - Proceedings - 2017 7th International Workshop on Advances in Sensors and Interfaces, IWASI 2017

PB - IEEE

CY - Danvers, MA

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Y2 - 15 June 2017 through 16 June 2017

ER -

Cryogenic CMOS Interfaces for Quantum Devices

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Keywords

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