Engineering Dissipation with Resistive Elements in Circuit Quantum Electrodynamics

Marco Cattaneo; Gheorghe Sorin Paraoanu

doi:10.1002/qute.202100054

Engineering Dissipation with Resistive Elements in Circuit Quantum Electrodynamics

Marco Cattaneo^*, Gheorghe Sorin Paraoanu

^*Tämän työn vastaava kirjoittaja

University of the Balearic Islands

Tutkimustuotos: Lehtiartikkeli › Review Article › vertaisarvioitu

30 Sitaatiot (Scopus)

205 Lataukset (Pure)

Abstrakti

The importance of dissipation engineering ranges from universal quantum computation to non-equilibrium quantum thermodynamics. In recent years, more and more theoretical and experimental studies have shown the relevance of this topic for circuit quantum electrodynamics, one of the major platforms in the race for a quantum computer. This article discusses how to simulate thermal baths by inserting resistive elements in networks of superconducting qubits. Apart from pedagogically reviewing the phenomenological and microscopic models of a resistor as thermal bath with Johnson–Nyquist noise, the paper introduces some new results in the weak coupling limit, showing that the most common examples of open quantum systems can be simulated through capacitively coupled superconducting qubits and resistors. The aim of the manuscript, written with a broad audience in mind, is to be both an instructive tutorial about how to derive and characterize the Hamiltonian of general dissipative superconducting circuits with capacitive coupling, and a review of the most relevant and topical theoretical and experimental works focused on resistive elements and dissipation engineering.

Alkuperäiskieli	Englanti
Artikkeli	2100054
Sivumäärä	30
Julkaisu	Advanced Quantum Technologies
Vuosikerta	4
Numero	11
Varhainen verkossa julkaisun päivämäärä	2021
DOI - pysyväislinkit	https://doi.org/10.1002/qute.202100054
Tila	Julkaistu - marrask. 2021
OKM-julkaisutyyppi	A2 Katsausartikkeli tieteellisessä aikakauslehdessä

Rahoitus

The authors acknowledge discussions with Jukka Pekola, Sabrina Maniscalco and Roberta Zambrini. M.C. would like to thank Adrián Parra‐Rodriguez and Íñigo Luis Egusquiza for valuable clarifications and extensive discussions on the derivation of the circuit Hamiltonian. He would also like to thank Lorenzo Gavassino for useful suggestions, as well as Antti Vaaranta for a careful reading of the manuscript and for spotting some typos. M.C. acknowledges funding from the Finnish Center of Excellence in Quantum Technology QTF (projects 312296, 336810), from the María de Maeztu Program for Units of Excellence in R&D (MDM‐ 2017‐0711), and from Fondazione Angelo della Riccia. G.S.P. would like to acknowledge support from the RADDESS programme (Project No. 328193) of the Academy of Finland and from the Grant No. FQXi‐IAF19‐06 (“Exploring the fundamental limits set by thermodynamics in the quantum regime”) of the Foundational Questions Institute Fund (FQXi), a donor advised fund of the Silicon Valley Community Foundation.

Pääsy asiakirjaan

10.1002/qute.202100054

qute.202100054Final published version, 1,64 MBLisenssi: CC BY

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Linkki julkaisuun Scopuksessa

Kvanttiteknologian huippuyksikkö
Paraoanu, G.-S. (Vastuullinen johtaja), McCord, J. (Projektin jäsen), Petrovnin, K. (Projektin jäsen), Dogra, S. (Projektin jäsen), Lan, D. (Projektin jäsen) & Cattaneo, M. (Projektin jäsen)
01/01/2018 → 31/12/2020
Projekti: Academy of Finland: Other research funding

Siteeraa tätä

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title = "Engineering Dissipation with Resistive Elements in Circuit Quantum Electrodynamics",

abstract = "The importance of dissipation engineering ranges from universal quantum computation to non-equilibrium quantum thermodynamics. In recent years, more and more theoretical and experimental studies have shown the relevance of this topic for circuit quantum electrodynamics, one of the major platforms in the race for a quantum computer. This article discusses how to simulate thermal baths by inserting resistive elements in networks of superconducting qubits. Apart from pedagogically reviewing the phenomenological and microscopic models of a resistor as thermal bath with Johnson–Nyquist noise, the paper introduces some new results in the weak coupling limit, showing that the most common examples of open quantum systems can be simulated through capacitively coupled superconducting qubits and resistors. The aim of the manuscript, written with a broad audience in mind, is to be both an instructive tutorial about how to derive and characterize the Hamiltonian of general dissipative superconducting circuits with capacitive coupling, and a review of the most relevant and topical theoretical and experimental works focused on resistive elements and dissipation engineering.",

keywords = "circuit quantum electrodynamics, dissipation engineering, open quantum systems, quantum Johnson-Nyquist noise, resistive elements",

author = "Marco Cattaneo and Paraoanu, \{Gheorghe Sorin\}",

note = "Funding Information: The authors acknowledge discussions with Jukka Pekola, Sabrina Maniscalco and Roberta Zambrini. M.C. would like to thank Adri{\'a}n Parra‐Rodriguez and {\'I}{\~n}igo Luis Egusquiza for valuable clarifications and extensive discussions on the derivation of the circuit Hamiltonian. He would also like to thank Lorenzo Gavassino for useful suggestions, as well as Antti Vaaranta for a careful reading of the manuscript and for spotting some typos. M.C. acknowledges funding from the Finnish Center of Excellence in Quantum Technology QTF (projects 312296, 336810), from the Mar{\'i}a de Maeztu Program for Units of Excellence in R\&D (MDM‐ 2017‐0711), and from Fondazione Angelo della Riccia. G.S.P. would like to acknowledge support from the RADDESS programme (Project No. 328193) of the Academy of Finland and from the Grant No. FQXi‐IAF19‐06 (“Exploring the fundamental limits set by thermodynamics in the quantum regime”) of the Foundational Questions Institute Fund (FQXi), a donor advised fund of the Silicon Valley Community Foundation. Publisher Copyright: {\textcopyright} 2021 The Authors. Advanced Quantum Technologies published by Wiley-VCH GmbH",

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AU - Cattaneo, Marco

AU - Paraoanu, Gheorghe Sorin

N1 - Funding Information: The authors acknowledge discussions with Jukka Pekola, Sabrina Maniscalco and Roberta Zambrini. M.C. would like to thank Adrián Parra‐Rodriguez and Íñigo Luis Egusquiza for valuable clarifications and extensive discussions on the derivation of the circuit Hamiltonian. He would also like to thank Lorenzo Gavassino for useful suggestions, as well as Antti Vaaranta for a careful reading of the manuscript and for spotting some typos. M.C. acknowledges funding from the Finnish Center of Excellence in Quantum Technology QTF (projects 312296, 336810), from the María de Maeztu Program for Units of Excellence in R&D (MDM‐ 2017‐0711), and from Fondazione Angelo della Riccia. G.S.P. would like to acknowledge support from the RADDESS programme (Project No. 328193) of the Academy of Finland and from the Grant No. FQXi‐IAF19‐06 (“Exploring the fundamental limits set by thermodynamics in the quantum regime”) of the Foundational Questions Institute Fund (FQXi), a donor advised fund of the Silicon Valley Community Foundation. Publisher Copyright: © 2021 The Authors. Advanced Quantum Technologies published by Wiley-VCH GmbH

PY - 2021/11

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N2 - The importance of dissipation engineering ranges from universal quantum computation to non-equilibrium quantum thermodynamics. In recent years, more and more theoretical and experimental studies have shown the relevance of this topic for circuit quantum electrodynamics, one of the major platforms in the race for a quantum computer. This article discusses how to simulate thermal baths by inserting resistive elements in networks of superconducting qubits. Apart from pedagogically reviewing the phenomenological and microscopic models of a resistor as thermal bath with Johnson–Nyquist noise, the paper introduces some new results in the weak coupling limit, showing that the most common examples of open quantum systems can be simulated through capacitively coupled superconducting qubits and resistors. The aim of the manuscript, written with a broad audience in mind, is to be both an instructive tutorial about how to derive and characterize the Hamiltonian of general dissipative superconducting circuits with capacitive coupling, and a review of the most relevant and topical theoretical and experimental works focused on resistive elements and dissipation engineering.

AB - The importance of dissipation engineering ranges from universal quantum computation to non-equilibrium quantum thermodynamics. In recent years, more and more theoretical and experimental studies have shown the relevance of this topic for circuit quantum electrodynamics, one of the major platforms in the race for a quantum computer. This article discusses how to simulate thermal baths by inserting resistive elements in networks of superconducting qubits. Apart from pedagogically reviewing the phenomenological and microscopic models of a resistor as thermal bath with Johnson–Nyquist noise, the paper introduces some new results in the weak coupling limit, showing that the most common examples of open quantum systems can be simulated through capacitively coupled superconducting qubits and resistors. The aim of the manuscript, written with a broad audience in mind, is to be both an instructive tutorial about how to derive and characterize the Hamiltonian of general dissipative superconducting circuits with capacitive coupling, and a review of the most relevant and topical theoretical and experimental works focused on resistive elements and dissipation engineering.

KW - circuit quantum electrodynamics

KW - dissipation engineering

KW - open quantum systems

KW - quantum Johnson-Nyquist noise

KW - resistive elements

UR - https://www.scopus.com/pages/publications/85115395023

U2 - 10.1002/qute.202100054

DO - 10.1002/qute.202100054

M3 - Review Article

AN - SCOPUS:85115395023

SN - 2511-9044

VL - 4

JO - Advanced Quantum Technologies

JF - Advanced Quantum Technologies

IS - 11

M1 - 2100054

ER -

Engineering Dissipation with Resistive Elements in Circuit Quantum Electrodynamics

Abstrakti

Rahoitus

Pääsy asiakirjaan

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Kvanttiteknologian huippuyksikkö

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