Exciton fine-structure splitting in GaN/AlN quantum dots

Kindel, Christian; Kako, Satoshi; Kawano, Takeshi; Oishi, H.; Arakawa, Yasuhiko; Hönig, Gerald; Winkelnkemper, Momme; Schliwa, A.; Hoffmann, A.; Bimberg, D.

doi:10.1103/physrevb.81.241309

Cited by 61 publications

(56 citation statements)

References 30 publications

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“…The overlap of two fully cross-polarized XX emission lines in Fig. 4a is mimicking a single, partially polarized emission line 31 . This observation can directly be confirmed by our simulated spectra (b) of the QD structure belonging to the upper green data point in Fig.…”

Section: Resultsmentioning

confidence: 99%

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Manifestation of unconventional biexciton states in quantum dots

et al. 2014

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Although semiconductor excitons consist of a fermionic subsystem (electron and hole), they carry an integer net spin similar to Cooper-electron-pairs. While the latter cause superconductivity by forming a Bose-Einstein-condensate, excitonic condensation is impeded by, for example, a fast radiative decay of the electron-hole pairs. Here, we investigate the behaviour of two electron-hole pairs in a quantum dot with wurtzite crystal structure evoking a charge carrier separation on the basis of large spontaneous and piezoelectric polarizations, thus reducing carrier overlap and consequently decay probabilities. As a direct consequence, we find a hybrid-biexciton complex with a water molecule-like charge distribution enabling anomalous spin configurations. In contrast to the conventional-biexciton complex with a net spin of s ¼ 0, the hybrid-biexciton exhibits s ¼ ± 3, leading to completely different photoluminescence signatures in addition to drastically enhanced charge carrier-binding energies. Consequently, the biexcitonic cascade via the dark exciton can be enhanced on the rise of temperature as approved by photon cross-correlation measurements.

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Section: Resultsmentioning

confidence: 99%

“…4, despite a much larger oscillator strength of X2 depending on the amount of finestructure splitting between X1 and X2 (ref. 31). In addition, this unbalance in the oscillator strengths explains the observations of E DB* in the low-temperature regime of Fig.…”

Section: Resultsmentioning

confidence: 99%

Manifestation of unconventional biexciton states in quantum dots

et al. 2014

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“…However, no asymmetry-induced x-and y-polarized FSS has been resolved for the majority of investigations of III-nitride-based QDs until recently, 13,14 when a huge splitting of 2-7 meV was interpreted as the FSS of exciton states confined in asymmetric GaN/AlN QDs. 15 This splitting is about two orders of magnitude larger than the typical asymmetry-induced FSS for III-arsenide-based systems.…”

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confidence: 90%

“…The FSS is resolved only in the unconventional geometry used to access the vertical polarization vector, and the obtained energy splittings are comparable to the typical values for III-arsenide systems and thus are significantly smaller than the asymmetry-induced FSS recently reported for GaN QDs. 15 The investigated sample was grown on a c-plane sapphire substrate at a temperature of 500…”

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confidence: 99%

Polarization-resolved fine-structure splitting of zero-dimensional InxGa1−xN excitons

et al. 2011

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“…It is straightforward to move to wurtzite structures, like GaN/AlN QDs, which show the advantage of much larger localization energies of the charge carriers and thus larger thermal stability, suggesting room-temperature operation of the SPEs. Recent experiments showed huge fine structure splitting up to 7 meV for GaN/AlN QDs [32][33][34]. Single photon emission up to RT has been indeed reported for QDs based on the (InGaAl)N material system.…”

Section: Single Qds As Q-bit or Entangled Photon Emittersmentioning

confidence: 99%

Semiconductor nanostructures for flying q-bits and green photonics

Bimberg

2018

Nanophotonics

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Breakthroughs in nanomaterials and nanoscience enable the development of novel photonic devices and systems ranging from the automotive sector, quantum cryptography to metropolitan area and access networks. Geometrical architecture presents a design parameter of device properties. Self-organization at surfaces in strained heterostructures drives the formation of quantum dots (QDs). Embedding QDs in photonic and electronic devices enables novel functionalities, advanced energy efficient communication, cyber security, or lighting systems. The recombination of excitons shows twofold degeneracy and Lorentzian broadening. The superposition of millions of excitonic recombinations from QDs in real devices leads to a Gaussian envelope. The material gain of QDs in lasers is orders of magnitude larger than that of bulk material and decoupled from the index of refraction, controlled by the properties of the carrier reservoir, thus enabling independent gain and index modulation. The threshold current density of QD lasers is lowest of all injection lasers, is less sensitive to defect generation, and does not depend on temperature below 80°C. QD lasers are hardly sensitive to back reflections and exhibit no filamentation. The recombination from single QDs inserted in light emitting diodes with current confining oxide apertures shows polarized single photons. Emission of ps pulses and date rates of 10 10 + bit upon direct modulation benefits from gain recovery within femtoseconds. Repetition rates of several 100 GHz were demonstrated upon mode-locking. Passively mode-locked QD lasers generate hat-like frequency combs, enabling Terabit data transmission. QD-based semiconductor optical amplifiers enable multi-wavelength amplification and switching and support multiple modulation formats.Keywords: quantum dot growth and electronic properties; quantum dot lasers; ultra-fast lasers and amplifiers; single q-bit emitters.

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Exciton fine-structure splitting in GaN/AlN quantum dots

Cited by 61 publications

References 30 publications

Manifestation of unconventional biexciton states in quantum dots

Manifestation of unconventional biexciton states in quantum dots

Polarization-resolved fine-structure splitting of zero-dimensional InxGa1−xN excitons

Semiconductor nanostructures for flying q-bits and green photonics

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