Cavity-enhanced real-time monitoring of single-charge jumps at the microsecond time scale

C. Arnold; V. Loo; A. Lemaître; I. Sagnes; O. Krebs; P. Voisin; P. Senellart; L. Lanco

doi:10.1103/PhysRevX.4.021004

Cavity-enhanced real-time monitoring of single-charge jumps at the microsecond time scale

C. Arnold
, V. Loo
, A. Lemaître
, I. Sagnes
, O. Krebs
, P. Voisin
, P. Senellart
, L. Lanco

École Polytechnique

CNRS
Laboratoire de Probabilités et Modèles Aléatoires

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We use fast coherent reflectivity measurements, in a strongly coupled quantum dot micropillar device, to monitor in real time single-charge jumps at the microsecond time scale. Thanks to the strong enhancement of light-matter interaction inside the cavity, and to a close to shot-noise-limited detection setup, the measurement rate is 5 orders of magnitude faster than with previous optical experiments of direct single-charge sensing with quantum dots. The monitored transitions, identified at any given time with a less than 0.2% error probability, correspond to a carrier being captured and then released by a single material defect. This high-speed technique opens the way for the real-time monitoring of other rapid single quantum events, such as the quantum jumps of a single spin.

langue originale	Anglais
Numéro d'article	021004
journal	Physical Review X
Volume	4
Numéro de publication	2
Les DOIs	https://doi.org/10.1103/PhysRevX.4.021004
état	Publié - 1 janv. 2014

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10.1103/PhysRevX.4.021004

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title = "Cavity-enhanced real-time monitoring of single-charge jumps at the microsecond time scale",

abstract = "We use fast coherent reflectivity measurements, in a strongly coupled quantum dot micropillar device, to monitor in real time single-charge jumps at the microsecond time scale. Thanks to the strong enhancement of light-matter interaction inside the cavity, and to a close to shot-noise-limited detection setup, the measurement rate is 5 orders of magnitude faster than with previous optical experiments of direct single-charge sensing with quantum dots. The monitored transitions, identified at any given time with a less than 0.2\% error probability, correspond to a carrier being captured and then released by a single material defect. This high-speed technique opens the way for the real-time monitoring of other rapid single quantum events, such as the quantum jumps of a single spin.",

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author = "C. Arnold and V. Loo and A. Lema{\^i}tre and I. Sagnes and O. Krebs and P. Voisin and P. Senellart and L. Lanco",

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T1 - Cavity-enhanced real-time monitoring of single-charge jumps at the microsecond time scale

AU - Arnold, C.

AU - Loo, V.

AU - Lemaître, A.

AU - Sagnes, I.

AU - Krebs, O.

AU - Voisin, P.

AU - Senellart, P.

AU - Lanco, L.

PY - 2014/1/1

Y1 - 2014/1/1

N2 - We use fast coherent reflectivity measurements, in a strongly coupled quantum dot micropillar device, to monitor in real time single-charge jumps at the microsecond time scale. Thanks to the strong enhancement of light-matter interaction inside the cavity, and to a close to shot-noise-limited detection setup, the measurement rate is 5 orders of magnitude faster than with previous optical experiments of direct single-charge sensing with quantum dots. The monitored transitions, identified at any given time with a less than 0.2% error probability, correspond to a carrier being captured and then released by a single material defect. This high-speed technique opens the way for the real-time monitoring of other rapid single quantum events, such as the quantum jumps of a single spin.

AB - We use fast coherent reflectivity measurements, in a strongly coupled quantum dot micropillar device, to monitor in real time single-charge jumps at the microsecond time scale. Thanks to the strong enhancement of light-matter interaction inside the cavity, and to a close to shot-noise-limited detection setup, the measurement rate is 5 orders of magnitude faster than with previous optical experiments of direct single-charge sensing with quantum dots. The monitored transitions, identified at any given time with a less than 0.2% error probability, correspond to a carrier being captured and then released by a single material defect. This high-speed technique opens the way for the real-time monitoring of other rapid single quantum events, such as the quantum jumps of a single spin.

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DO - 10.1103/PhysRevX.4.021004

M3 - Article

AN - SCOPUS:84903160267

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JO - Physical Review X

JF - Physical Review X

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ER -

Cavity-enhanced real-time monitoring of single-charge jumps at the microsecond time scale

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