Observation of quantum many-body effects due to zero point fluctuations in superconducting circuits

Observation of quantum many-body effects due to zero point fluctuations in superconducting circuits

Electromagnetic fields possess zero point fluctuations which lead to observable effects such as the Lamb shift and the Casimir effect. In the traditional quantum optics domain, these corrections remain perturbative due to the smallness of the fine structure constant. To provide a direct observation...

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Bibliographic Details
Published in:Nature communications Vol. 10; no. 1; pp. 5259 - 8
Main Authors: Léger, Sébastien, Puertas-Martínez, Javier, Bharadwaj, Karthik, Dassonneville, Rémy, Delaforce, Jovian, Foroughi, Farshad, Milchakov, Vladimir, Planat, Luca, Buisson, Olivier, Naud, Cécile, Hasch-Guichard, Wiebke, Florens, Serge, Snyman, Izak, Roch, Nicolas
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 20-11-2019
Nature Publishing Group
Nature Portfolio
Subjects:
639/766/119/2795
639/766/483/3926
Circuits
Condensed Matter
Electromagnetic fields
Experiments
Fine structure
Fluctuations
Frequency shift
High impedance
Humanities and Social Sciences
Impedance
Josephson junctions
Linearity
Mesoscopic Systems and Quantum Hall Effect
multidisciplinary
Nonlinearity
Optics
Oscillations
Physics
Quantum optics
Quantum theory
Qubits (quantum computing)
Science
Science (multidisciplinary)
Transmission lines
Ultrastructure
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Summary:Electromagnetic fields possess zero point fluctuations which lead to observable effects such as the Lamb shift and the Casimir effect. In the traditional quantum optics domain, these corrections remain perturbative due to the smallness of the fine structure constant. To provide a direct observation of non-perturbative effects driven by zero point fluctuations in an open quantum system we wire a highly non-linear Josephson junction to a high impedance transmission line, allowing large phase fluctuations across the junction. Consequently, the resonance of the former acquires a relative frequency shift that is orders of magnitude larger than for natural atoms. Detailed modeling confirms that this renormalization is non-linear and quantum. Remarkably, the junction transfers its non-linearity to about thirty environmental modes, a striking back-action effect that transcends the standard Caldeira-Leggett paradigm. This work opens many exciting prospects for longstanding quests such as the tailoring of many-body Hamiltonians in the strongly non-linear regime, the observation of Bloch oscillations, or the development of high-impedance qubits. Advances in the design and fabrication of superconducting devices enable physicists to design and monitor quantum electronic systems in synthetic environments. Here the authors observe how many-body effects influence the zero-point motion of a Josephson junction coupled to a high impedance transmission line.
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ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-019-13199-x