Vanishing fine-structure splittings in telecommunication-wavelength quantum dots grown on (111)A surfaces by droplet epitaxy

Liu, Xiangming; Ha, Neul; Nakajima, Hirochika; Mano, Takaaki; Kuroda, Takashi; Urbaszek, B.; Kumano, H.; Suemune, I.; Sakuma, Yoshiki; Sakoda, Kazuaki

doi:10.1103/physrevb.90.081301

Cited by 45 publications

(57 citation statements)

References 63 publications

(55 reference statements)

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“…Previous reports have shown a correlation between the emission wavelength and the FSS of the quantum dot for both SK dots [7] and DE dots [8]. However, for the DE QDs studied here, we observe no obvious correlation, as shown in Fig.…”

Section: Discussioncontrasting

confidence: 52%

“…Production of quantum dots with naturally small FSS may be achieved in special cases, by self-assembled growth of InAs quantum dots around 885 nm, where an inversion of the wave-function symmetry is observed [7], or growth on (111) surfaces [8][9][10], aided by the underlying C 3v crystal symmetry which very often results in dot density preventing the spectral isolation of individual lines [11][12][13]. Another approach is the growth of strain-free GaAs=ðAl; GaÞAs QDs in locally etched pits [14].…”

Section: Introductionmentioning

confidence: 99%

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Universal Growth Scheme for Quantum Dots with Low Fine-Structure Splitting at Various Emission Wavelengths

et al. 2017

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Efficient sources of individual pairs of entangled photons are required for quantum networks to operate using fiber-optic infrastructure. Entangled light can be generated by quantum dots (QDs) with naturally small fine-structure splitting (FSS) between exciton eigenstates. Moreover, QDs can be engineered to emit at standard telecom wavelengths. To achieve sufficient signal intensity for applications, QDs have been incorporated into one-dimensional optical microcavities. However, combining these properties in a single device has so far proved elusive. Here, we introduce a growth strategy to realize QDs with small FSS in the conventional telecom band, and within an optical cavity. Our approach employs ''droplet-epitaxy'' of InAs quantum dots on (001) substrates. We show the scheme improves the symmetry of the dots by 72%. Furthermore, our technique is universal, and produces low FSS QDs by molecular beam epitaxy on GaAs emitting at ∼900 nm, and metal-organic vapor-phase epitaxy on InP emitting at ∼1550 nm, with mean FSS 4× smaller than for Stranski-Krastanow QDs.

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Section: Discussioncontrasting

confidence: 52%

Section: Introductionmentioning

confidence: 99%

Universal Growth Scheme for Quantum Dots with Low Fine-Structure Splitting at Various Emission Wavelengths

et al. 2017

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“…2). While vanishing FSS of QDs grown along (111) direction is predicted theoretically 20,42,43 and typically small values were obtained experimentally, 21,44,45 there are a number of effects that can cause deviation from theory. QD alloy disorder is a potential cause of reduced symmetry.…”

Section: Resultsmentioning

confidence: 99%

Conditions for entangled photon emission from (111)B site-controlled pyramidal quantum dots

Juška

Murray

Dimastrodonato

et al. 2015

Journal of Applied Physics

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A study of highly symmetric site-controlled Pyramidal In 0.25 Ga 0.75 As quantum dots (QDs) is presented. It is discussed that polarization-entangled photons can be also obtained from Pyramidal QDs of different designs from the one already reported in Juska et al. (Nat. Phot. 7, 527, 2013).Moreover, some of the limitations for a higher density of entangled photon emitters are addressed. Among these issues are (1) a remaining small fine-structure splitting and (2) an effective QD charging under non-resonant excitation conditions, which strongly reduce the number of useful biexcitonexciton recombination events. A possible solution of the charging problem is investigated exploiting a dual-wavelength excitation technique, which allows a gradual QD charge tuning from strongly negative to positive and, eventually, efficient detection of entangled photons from QDs, which would be otherwise ineffective under a single-wavelength (non-resonant) excitation.

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“…In contrast to the structures with C 2v sym metry, in quantum dots with C 3v symmetry, the aniso tropic doublet splitting is forbidden [7,8]. In a number of works, the authors observed a very small (Շ10 μeV) anisotropic splitting in the [111] quantum dots imme diately after the growth (without further treatment) [9][10][11][12], as well as the generation of entangled photon pairs [13,14].…”

Section: Introductionmentioning

confidence: 94%

Fine structure of electron-hole complexes in trigonal quantum dots

Durnev

2015

Phys. Solid State

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A theory of the Zeeman effect and fine structure of the energy spectrum of electron-hole com plexes in highly symmetric quantum dots grown along the [111] direction from materials with a zinc blende lattice has been presented. In the studied quantum dots with C 3v point symmetry, the Zeeman effect for a heavy hole in a magnetic field B || [111] has an unusual form: in addition to the diagonal component (g h1 ), the effective tensor of g factors contains the off diagonal element (g h2 ). For g h2 ≠ 0, there is a magnetically induced mixing of heavy hole states, which explains two additional lines observed in experimental photolu minescence spectra of excitons and trions. A microscopic theory of the effective g factors g h1 and g h2 within the Luttinger Hamiltonian in the spherical approximation has been discussed, as well as additional contribu tions to the off diagonal element g h2 due to the warping of the spectrum of holes. The results of theoretical calculations of the g factors g h1 and g h2 for quantum dots based on GaAs have been compared with the exper imental data.

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Vanishing fine-structure splittings in telecommunication-wavelength quantum dots grown on (111)A surfaces by droplet epitaxy

Cited by 45 publications

References 63 publications

Universal Growth Scheme for Quantum Dots with Low Fine-Structure Splitting at Various Emission Wavelengths

Universal Growth Scheme for Quantum Dots with Low Fine-Structure Splitting at Various Emission Wavelengths

Conditions for entangled photon emission from (111)B site-controlled pyramidal quantum dots

Fine structure of electron-hole complexes in trigonal quantum dots

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