Quantum-dot excitons in nanostructured environments

Jorn M Hvam; Søren Stobbe; Peter Lodahl

doi:10.1002/pssb.201000634

Quantum-dot excitons in nanostructured environments

Jorn M Hvam, Søren Stobbe, Peter Lodahl

1 Citation (Scopus)

Abstract

The interaction between light and quantum-dot (QD) excitons is strongly influenced by the environment in which the QD is placed. We have investigated the interaction by measuring the time-resolved spontaneous-emission rate of QD excitons in different nanostructured environments. Thereby, we have determined the oscillator strength, quantum efficiency and spin-flip rates of QD excitons as well as their dependencies on emission wavelength and QD size. Enhancement and inhibition of QD spontaneous emission in photonic crystal membranes (PCMs) is observed. Efficient coupling to PCM waveguides is demonstrated and the influence of disorder is discussed. The findings have a strong bearing on future nanophotonic devices. QD emitter placed in a photonic crystal membrane waveguide (artist's view).

Original language	English
Journal	IPPS physica status solidi (b)
Volume	248
Issue number	2
Pages (from-to)	375-383
ISSN	0370-1972
DOIs	https://doi.org/10.1002/pssb.201000634
Publication status	Published - 1 Feb 2011
Externally published	Yes

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title = "Quantum-dot excitons in nanostructured environments",

abstract = "The interaction between light and quantum-dot (QD) excitons is strongly influenced by the environment in which the QD is placed. We have investigated the interaction by measuring the time-resolved spontaneous-emission rate of QD excitons in different nanostructured environments. Thereby, we have determined the oscillator strength, quantum efficiency and spin-flip rates of QD excitons as well as their dependencies on emission wavelength and QD size. Enhancement and inhibition of QD spontaneous emission in photonic crystal membranes (PCMs) is observed. Efficient coupling to PCM waveguides is demonstrated and the influence of disorder is discussed. The findings have a strong bearing on future nanophotonic devices. QD emitter placed in a photonic crystal membrane waveguide (artist's view).",

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T1 - Quantum-dot excitons in nanostructured environments

AU - Hvam, Jorn M

AU - Stobbe, Søren

AU - Lodahl, Peter

PY - 2011/2/1

Y1 - 2011/2/1

N2 - The interaction between light and quantum-dot (QD) excitons is strongly influenced by the environment in which the QD is placed. We have investigated the interaction by measuring the time-resolved spontaneous-emission rate of QD excitons in different nanostructured environments. Thereby, we have determined the oscillator strength, quantum efficiency and spin-flip rates of QD excitons as well as their dependencies on emission wavelength and QD size. Enhancement and inhibition of QD spontaneous emission in photonic crystal membranes (PCMs) is observed. Efficient coupling to PCM waveguides is demonstrated and the influence of disorder is discussed. The findings have a strong bearing on future nanophotonic devices. QD emitter placed in a photonic crystal membrane waveguide (artist's view).

AB - The interaction between light and quantum-dot (QD) excitons is strongly influenced by the environment in which the QD is placed. We have investigated the interaction by measuring the time-resolved spontaneous-emission rate of QD excitons in different nanostructured environments. Thereby, we have determined the oscillator strength, quantum efficiency and spin-flip rates of QD excitons as well as their dependencies on emission wavelength and QD size. Enhancement and inhibition of QD spontaneous emission in photonic crystal membranes (PCMs) is observed. Efficient coupling to PCM waveguides is demonstrated and the influence of disorder is discussed. The findings have a strong bearing on future nanophotonic devices. QD emitter placed in a photonic crystal membrane waveguide (artist's view).

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DO - 10.1002/pssb.201000634

M3 - Journal article

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SP - 375

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JO - Physica Status Solidi (B): Basic Research

JF - Physica Status Solidi (B): Basic Research

IS - 2

ER -

Quantum-dot excitons in nanostructured environments

Abstract

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