Resonance fluorescence revival in a voltage-controlled semiconductor quantum dot

Antoine Reigue; Aristide Lemaître; Carmen Gomez Carbonell; Christian Ulysse; Kamel Merghem; Stéphane Guilet; Richard Hostein; Valia Voliotis

doi:10.1063/1.5010757

Resonance fluorescence revival in a voltage-controlled semiconductor quantum dot

Antoine Reigue
, Aristide Lemaître
, Carmen Gomez Carbonell
, Christian Ulysse
, Kamel Merghem
, Stéphane Guilet
, Richard Hostein
, Valia Voliotis

Research output: Contribution to journal › Article › peer-review

Abstract

We demonstrate systematic resonance fluorescence recovery with near-unity emission efficiency in single quantum dots embedded in a charge-tunable device in a wave-guiding geometry. The quantum dot charge state is controlled by a gate voltage, through carrier tunneling from a close-lying Fermi sea, stabilizing the resonantly photocreated electron-hole pair. The electric field cancels out the charging/discharging mechanisms from nearby traps toward the quantum dots, responsible for the usually observed inhibition of the resonant fluorescence. Fourier transform spectroscopy as a function of the applied voltage shows a strong increase in the coherence time though not reaching the radiative limit. These charge controlled quantum dots can act as quasi-perfect deterministic single-photon emitters, with one laser pulse converted into one emitted single photon.

Original language	English
Article number	073103
Journal	Applied Physics Letters
Volume	112
Issue number	7
DOIs	https://doi.org/10.1063/1.5010757
Publication status	Published - 12 Feb 2018

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10.1063/1.5010757

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title = "Resonance fluorescence revival in a voltage-controlled semiconductor quantum dot",

abstract = "We demonstrate systematic resonance fluorescence recovery with near-unity emission efficiency in single quantum dots embedded in a charge-tunable device in a wave-guiding geometry. The quantum dot charge state is controlled by a gate voltage, through carrier tunneling from a close-lying Fermi sea, stabilizing the resonantly photocreated electron-hole pair. The electric field cancels out the charging/discharging mechanisms from nearby traps toward the quantum dots, responsible for the usually observed inhibition of the resonant fluorescence. Fourier transform spectroscopy as a function of the applied voltage shows a strong increase in the coherence time though not reaching the radiative limit. These charge controlled quantum dots can act as quasi-perfect deterministic single-photon emitters, with one laser pulse converted into one emitted single photon.",

author = "Antoine Reigue and Aristide Lema{\^i}tre and \{Gomez Carbonell\}, Carmen and Christian Ulysse and Kamel Merghem and St{\'e}phane Guilet and Richard Hostein and Valia Voliotis",

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T1 - Resonance fluorescence revival in a voltage-controlled semiconductor quantum dot

AU - Reigue, Antoine

AU - Lemaître, Aristide

AU - Gomez Carbonell, Carmen

AU - Ulysse, Christian

AU - Merghem, Kamel

AU - Guilet, Stéphane

AU - Hostein, Richard

AU - Voliotis, Valia

PY - 2018/2/12

Y1 - 2018/2/12

N2 - We demonstrate systematic resonance fluorescence recovery with near-unity emission efficiency in single quantum dots embedded in a charge-tunable device in a wave-guiding geometry. The quantum dot charge state is controlled by a gate voltage, through carrier tunneling from a close-lying Fermi sea, stabilizing the resonantly photocreated electron-hole pair. The electric field cancels out the charging/discharging mechanisms from nearby traps toward the quantum dots, responsible for the usually observed inhibition of the resonant fluorescence. Fourier transform spectroscopy as a function of the applied voltage shows a strong increase in the coherence time though not reaching the radiative limit. These charge controlled quantum dots can act as quasi-perfect deterministic single-photon emitters, with one laser pulse converted into one emitted single photon.

AB - We demonstrate systematic resonance fluorescence recovery with near-unity emission efficiency in single quantum dots embedded in a charge-tunable device in a wave-guiding geometry. The quantum dot charge state is controlled by a gate voltage, through carrier tunneling from a close-lying Fermi sea, stabilizing the resonantly photocreated electron-hole pair. The electric field cancels out the charging/discharging mechanisms from nearby traps toward the quantum dots, responsible for the usually observed inhibition of the resonant fluorescence. Fourier transform spectroscopy as a function of the applied voltage shows a strong increase in the coherence time though not reaching the radiative limit. These charge controlled quantum dots can act as quasi-perfect deterministic single-photon emitters, with one laser pulse converted into one emitted single photon.

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DO - 10.1063/1.5010757

M3 - Article

AN - SCOPUS:85042221669

SN - 0003-6951

VL - 112

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 7

M1 - 073103

ER -

Resonance fluorescence revival in a voltage-controlled semiconductor quantum dot

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