Temporal monitoring of nonresonant feeding of semiconductor nanocavity modes by quantum dot multiexciton transitions

A. Laucht; M. Kaniber; A. Mohtashami; N. Hauke; M. Bichler; J. J. Finley

doi:10.1103/PhysRevB.81.241302

Temporal monitoring of nonresonant feeding of semiconductor nanocavity modes by quantum dot multiexciton transitions

A. Laucht, M. Kaniber, A. Mohtashami, N. Hauke, M. Bichler, J. J. Finley

Walter Schottky Institut

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

51 Scopus citations

Abstract

We experimentally investigate the nonresonant (ΔE>5 meV) feeding of photons into the optical mode of a two-dimensional photonic crystal nanocavity by quantum dot multiexciton transitions. Power-dependent photoluminescence measurements reveal a superlinear power dependence of the mode emission, indicating that the emission stems from multiexcitons. By monitoring the temporal evolution of the photoluminescence spectrum, we observe a clear anticorrelation of the mode and single exciton emission; the mode emission quenches as the population in the system reduces toward the single exciton level while the intensity of the mode emission tracks the multiexciton transitions. Our results lend strong support to a recently proposed mechanism mediating the strongly nonresonant feeding of photons into the cavity mode.

Original language	English
Article number	241302
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	81
Issue number	24
DOIs	https://doi.org/10.1103/PhysRevB.81.241302
State	Published - 2 Jun 2010

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title = "Temporal monitoring of nonresonant feeding of semiconductor nanocavity modes by quantum dot multiexciton transitions",

abstract = "We experimentally investigate the nonresonant (ΔE>5 meV) feeding of photons into the optical mode of a two-dimensional photonic crystal nanocavity by quantum dot multiexciton transitions. Power-dependent photoluminescence measurements reveal a superlinear power dependence of the mode emission, indicating that the emission stems from multiexcitons. By monitoring the temporal evolution of the photoluminescence spectrum, we observe a clear anticorrelation of the mode and single exciton emission; the mode emission quenches as the population in the system reduces toward the single exciton level while the intensity of the mode emission tracks the multiexciton transitions. Our results lend strong support to a recently proposed mechanism mediating the strongly nonresonant feeding of photons into the cavity mode.",

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AU - Laucht, A.

AU - Kaniber, M.

AU - Mohtashami, A.

AU - Hauke, N.

AU - Bichler, M.

AU - Finley, J. J.

PY - 2010/6/2

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N2 - We experimentally investigate the nonresonant (ΔE>5 meV) feeding of photons into the optical mode of a two-dimensional photonic crystal nanocavity by quantum dot multiexciton transitions. Power-dependent photoluminescence measurements reveal a superlinear power dependence of the mode emission, indicating that the emission stems from multiexcitons. By monitoring the temporal evolution of the photoluminescence spectrum, we observe a clear anticorrelation of the mode and single exciton emission; the mode emission quenches as the population in the system reduces toward the single exciton level while the intensity of the mode emission tracks the multiexciton transitions. Our results lend strong support to a recently proposed mechanism mediating the strongly nonresonant feeding of photons into the cavity mode.

AB - We experimentally investigate the nonresonant (ΔE>5 meV) feeding of photons into the optical mode of a two-dimensional photonic crystal nanocavity by quantum dot multiexciton transitions. Power-dependent photoluminescence measurements reveal a superlinear power dependence of the mode emission, indicating that the emission stems from multiexcitons. By monitoring the temporal evolution of the photoluminescence spectrum, we observe a clear anticorrelation of the mode and single exciton emission; the mode emission quenches as the population in the system reduces toward the single exciton level while the intensity of the mode emission tracks the multiexciton transitions. Our results lend strong support to a recently proposed mechanism mediating the strongly nonresonant feeding of photons into the cavity mode.

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Temporal monitoring of nonresonant feeding of semiconductor nanocavity modes by quantum dot multiexciton transitions

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