Your search keyword '"Cottet N"' showing total 6 results

1. Observing a quantum Maxwell demon at work

Author

Cottet, N., Jezouin, S., Bretheau, L., Campagne-Ibarcq, P., Ficheux, Q., Anders, J., Auffèves, A., Azouit, R., Rouchon, P., and Huard, B.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Statistical Mechanics

Abstract

In apparent contradiction to the laws of thermodynamics, Maxwell's demon is able to cyclically extract work from a system in contact with a thermal bath exploiting the information about its microstate. The resolution of this paradox required the insight that an intimate relationship exists between information and thermodynamics. Here, we realize a Maxwell demon experiment that tracks the state of each constituent both in the classical and quantum regimes. The demon is a microwave cavity that encodes quantum information about a superconducting qubit and converts information into work by powering up a propagating microwave pulse by stimulated emission. Thanks to the high level of control of superconducting circuits, we directly measure the extracted work and quantify the entropy remaining in the demon's memory. This experiment provides an enlightening illustration of the interplay of thermodynamics with quantum information.

Published

2017

2. Autoparametric Resonance Extending the Bit-Flip Time of a Cat Qubit up to 0.3 s

Author

Marquet, A., primary, Essig, A., additional, Cohen, J., additional, Cottet, N., additional, Murani, A., additional, Albertinale, E., additional, Dupouy, S., additional, Bienfait, A., additional, Peronnin, T., additional, Jezouin, S., additional, Lescanne, R., additional, and Huard, B., additional

Published

2024

3. Using Spontaneous Emission of a Qubit as a Resource for Feedback Control

Author

Campagne-Ibarcq, P., Jezouin, S., Cottet, N., Six, P., Bretheau, L., Mallet, F., Sarlette, A., Rouchon, P., and Huard, B.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Persistent control of a transmon qubit is performed by a feedback protocol based on continuous heterodyne measurement of its fluorescence. By driving the qubit and cavity with microwave signals whose amplitudes depend linearly on the instantaneous values of the quadratures of the measured fluorescence field, we show that it is possible to stabilize permanently the qubit in any targeted state. Using a Josephson mixer as a phase-preserving amplifier, it was possible to reach a total measurement efficiency $\eta$=35%, leading to a maximum of 59% of excitation and 44% of coherence for the stabilized states. The experiment demonstrates multiple-input multiple-output analog Markovian feedback in the quantum regime., Comment: Supplementary material can be found as an ancillary object

Published

2016

4. Energetics of a Single Qubit Gate

Author

Stevens, J., primary, Szombati, D., additional, Maffei, M., additional, Elouard, C., additional, Assouly, R., additional, Cottet, N., additional, Dassonneville, R., additional, Ficheux, Q., additional, Zeppetzauer, S., additional, Bienfait, A., additional, Jordan, A. N., additional, Auffèves, A., additional, and Huard, B., additional

Published

2022

5. Using Spontaneous Emission of a Qubit as a Resource for Feedback Control

Author

Campagne-Ibarcq, P., primary, Jezouin, S., additional, Cottet, N., additional, Six, P., additional, Bretheau, L., additional, Mallet, F., additional, Sarlette, A., additional, Rouchon, P., additional, and Huard, B., additional

Published

2016

6. Electron shelving of a superconducting artificial atom.

Author

Cottet N, Xiong H, Nguyen LB, Lin YH, and Manucharyan VE

Abstract

Interfacing long-lived qubits with propagating photons is a fundamental challenge in quantum technology. Cavity and circuit quantum electrodynamics (cQED) architectures rely on an off-resonant cavity, which blocks the qubit emission and enables a quantum non-demolition (QND) dispersive readout. However, no such buffer mode is necessary for controlling a large class of three-level systems that combine a metastable qubit transition with a bright cycling transition, using the electron shelving effect. Here we demonstrate shelving of a circuit atom, fluxonium, placed inside a microwave waveguide. With no cavity modes in the setup, the qubit coherence time exceeds 50 μs, and the cycling transition's radiative lifetime is under 100 ns. By detecting a homodyne fluorescence signal from the cycling transition, we implement a QND readout of the qubit and account for readout errors using a minimal optical pumping model. Our result establishes a resource-efficient (cavityless) alternative to cQED for controlling superconducting qubits., (© 2021. The Author(s).)

Published

2021