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Abstract:

Transient gain spectra were measured for an In0.02Ga 0.98N / In0.16Ga0.84N multiple quantum well using the variable stripe length method (VSLM) in combination with the ultrafast optical Kerr gate (OKG) technique. Gain dynamics were measured for a range of excitation lengths from short (50 μm) to long (350 μm) stripes with the sample under femtosecond photoexcitation. Analysis of the temporal behaviour of gain and chemical potential suggests that stimulated emission originates from a photoexcited electron-hole plasma at early times; at later times localized states dominate as the electron-hole plasma becomes exhausted. Gain reduction at early times is attributable to coupling of the electron-hole plasma with photons along the stripe, whilst localized states are less susceptible to gain saturation. © 2004 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Abstract:

This paper reports on time-integrated and time-resolved microphotoluminescence (μ-PL) measurements of single InGaN quantum dots (QDs). The linewidths of the μ-PL peaks originating from single metal-organic vapor phase expitaxy-grown III/V InGaN QDs are measured, implying dephasing times of at least 5 ps. Temporal fluctuations of the QD emission energy are observed, and these are explained in terms of randomly generated local electric fields inducing a Stark shift in the optical emission of the InGaN QDs. Time-resolved measurements demonstrate that decay dynamics from single InGaN QDs are exponential in nature. Measurements of the effect of temperature upon the recombination times in individual InGaN QDs have been performed from 4 to 60 K.

Abstract:

We describe a lithographic process for the fabrication of small size optical apertures, together with large alignment marks to locate the aperture position during measurements in an optical cryostat. The aperture size is chosen to isolate a small number of dots from a dense self-assembled array of InGaN dots. The pattern was exposed in a chemically-amplified resist, UVIII and transferred to the underlying aluminium layer using reactive ion etching. Micro-photoluminescence measurements show sharp spectral lines of width similar to700 mueV at 4.2 K (limited by the spectral resolution of the monochromator), confirming the isolation of a single quantum dot. (C) 2004 Elsevier B.V. All rights reserved.

Abstract:

The optical transmissions in single III/V (InGaN) quantum dots (QD) were measured as a function of time. The temporal fluctuations in microphotoluminescence peak position and linewidth were demonstrated and attributed to spectral diffusion processes. It was found that the temporal variations originated from randomly generated local electric fields inducing a Stark shift in the optical emission peaks of the InGaN QDs. It was also demonstrated that the spectral diffusion must be considered in the study of exciton optical transitions in single nitride based QDs.