Cat-qubits for quantum computation

Mazyar Mirrahimi

doi:10.1016/j.crhy.2016.07.011

Cat-qubits for quantum computation

Research output: Contribution to journal › Short survey › peer-review

Abstract

The development of quantum Josephson circuits has created a strong expectation for reliable processing of quantum information. While this progress has already led to various proof-of-principle experiments on small-scale quantum systems, a major scaling step is required towards many-qubit protocols. Fault-tolerant computation with protected logical qubits usually comes at the expense of a significant overhead in the hardware. Each of the involved physical qubits still needs to satisfy the best achieved properties (coherence times, coupling strengths and tunability). Here, and in the aim of addressing alternative approaches to deal with these obstacles, I overview a series of recent theoretical proposals, and the experimental developments following these proposals, to enable a hardware-efficient paradigm for quantum memory protection and universal quantum computation.

Translated title of the contribution	Qubits de chat pour le calcul quantique
Original language	English
Pages (from-to)	778-787
Number of pages	10
Journal	Comptes Rendus Physique
Volume	17
Issue number	7
DOIs	https://doi.org/10.1016/j.crhy.2016.07.011
Publication status	Published - 1 Aug 2016
Externally published	Yes

Keywords

Quantum error correction
Quantum memory
Quantum superconducting circuits
Schrödinger cat states
Universal quantum computation

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title = "Cat-qubits for quantum computation",

abstract = "The development of quantum Josephson circuits has created a strong expectation for reliable processing of quantum information. While this progress has already led to various proof-of-principle experiments on small-scale quantum systems, a major scaling step is required towards many-qubit protocols. Fault-tolerant computation with protected logical qubits usually comes at the expense of a significant overhead in the hardware. Each of the involved physical qubits still needs to satisfy the best achieved properties (coherence times, coupling strengths and tunability). Here, and in the aim of addressing alternative approaches to deal with these obstacles, I overview a series of recent theoretical proposals, and the experimental developments following these proposals, to enable a hardware-efficient paradigm for quantum memory protection and universal quantum computation.",

keywords = "Quantum error correction, Quantum memory, Quantum superconducting circuits, Schr{\"o}dinger cat states, Universal quantum computation",

author = "Mazyar Mirrahimi",

note = "Publisher Copyright: {\textcopyright} 2016 Acad{\'e}mie des sciences",

year = "2016",

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doi = "10.1016/j.crhy.2016.07.011",

language = "English",

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T1 - Cat-qubits for quantum computation

AU - Mirrahimi, Mazyar

PY - 2016/8/1

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N2 - The development of quantum Josephson circuits has created a strong expectation for reliable processing of quantum information. While this progress has already led to various proof-of-principle experiments on small-scale quantum systems, a major scaling step is required towards many-qubit protocols. Fault-tolerant computation with protected logical qubits usually comes at the expense of a significant overhead in the hardware. Each of the involved physical qubits still needs to satisfy the best achieved properties (coherence times, coupling strengths and tunability). Here, and in the aim of addressing alternative approaches to deal with these obstacles, I overview a series of recent theoretical proposals, and the experimental developments following these proposals, to enable a hardware-efficient paradigm for quantum memory protection and universal quantum computation.

AB - The development of quantum Josephson circuits has created a strong expectation for reliable processing of quantum information. While this progress has already led to various proof-of-principle experiments on small-scale quantum systems, a major scaling step is required towards many-qubit protocols. Fault-tolerant computation with protected logical qubits usually comes at the expense of a significant overhead in the hardware. Each of the involved physical qubits still needs to satisfy the best achieved properties (coherence times, coupling strengths and tunability). Here, and in the aim of addressing alternative approaches to deal with these obstacles, I overview a series of recent theoretical proposals, and the experimental developments following these proposals, to enable a hardware-efficient paradigm for quantum memory protection and universal quantum computation.

KW - Quantum error correction

KW - Quantum memory

KW - Quantum superconducting circuits

KW - Schrödinger cat states

KW - Universal quantum computation

U2 - 10.1016/j.crhy.2016.07.011

DO - 10.1016/j.crhy.2016.07.011

M3 - Short survey

AN - SCOPUS:84979650430

SN - 1631-0705

VL - 17

SP - 778

EP - 787

JO - Comptes Rendus Physique

JF - Comptes Rendus Physique

IS - 7

ER -

Cat-qubits for quantum computation

Abstract

Keywords

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