Dynamic Acoustic Control of Individual Optically Active Quantum Dot-like Emission Centers in Heterostructure Nanowires

Weiß, Matthias; Kinzel, Jörg B.; Schülein, Florian J. R.; Heigl, Michael; Rudolph, Daniel; Morkötter, Stefanie; Döblinger, Markus; Bichler, Max; Abstreiter, G.; Finley, Jonathan J.; Koblmüller, Gregor; Wixforth, Achim; Krenner, Hubert J.

doi:10.1021/nl4040434

Cited by 66 publications

(98 citation statements)

References 56 publications

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“…Furthermore, the φ-dependency of h density is anticorrelated to that of e providing further evidence for the the preferential formation of negatively charged excitons. The emission lines similar to those reported by Heiss et al in [33] exhibit also a characteristic SAW-response [30]. This, however, features characteristic differences to that reported here since both the emission center and the driving mechanism are of different nature: (i) In Ref.…”

Section: Acoustic Control Of Qd Occupancy Statesupporting

confidence: 80%

“…The emission of the 2 nm QW extends over a ∼ 100 meV wide energy band centered at E QW = 1.7 eV. This emission is not observed for a reference sample without a radial QW, which excludes other types of emitter systems [31,33,30] as its origin. The large spread of the emission energy is from the (i) the small nominal thickness and (ii) the fact that growth occurs on the [110]-type facet of a NW.…”

Section: Sample and Optical Characterizationmentioning

confidence: 77%

“…At such low acoustic amplitudes the contribution of SAW-induced lateral electric fields are weak [48] and the observed spectral shift is dominated by the strain contribution. [49,30] The extracted relative spectral tuning ∆E strain of 1X 0 and 1X − are plotted as a function of φ in Fig. 2 (b).…”

Section: Dynamic Spectral Modulation and Saw Phase Calibrationmentioning

confidence: 99%

“…Taken together, the maximum (minimum) emission energies are observed for the value of φ at which p is maximum positive (negative). For the crystal cut of our LiNbO 3 substrate we can derive the φ-dependence of the SAW-induced modulation of the conduction (CB) and valence band (VB) within the GaAs NW using finite element modeling (FEM) [30] which is shown in Fig. 2(c) for times t = 0 (i.e.…”

Section: Dynamic Spectral Modulation and Saw Phase Calibrationmentioning

confidence: 99%

“…Radio frequency surface acoustic waves (SAWs) represent a particularly attractive and powerful tool to probe and dynamically control charge excitations in semiconductor heterostructure including Quantum Hall systems [12,13,14], charge transport in oneand two-dimensional electron channels [15,16], transport of charges [17,18,19], spins [20] or dipolar excitons [21] and precisely timed carrier injection into QDs for low-jitter single photon emission [22,23,24,25]. Recently, these concepts have been transferred to intrinsic nanowires (NWs) [26] and nanotubes [27] and NWs containing complex radial and axial heterostructures [28,29,30].…”

Section: Introductionmentioning

confidence: 99%

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Radio frequency occupancy state control of a single nanowire quantum dot

Weiß¹,

Schülein²,

Kinzel³

et al. 2014

J. Phys. D: Appl. Phys.

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Abstract.The excitonic occupancy state of a single, nanowire-based, heterostructure quantum dot is dynamically programmed by a surface acoustic wave. The quantum dot is formed by an interface or thickness fluctuation of a GaAs QW embedded in a AlGaAs shell of a GaAs − AlGaAs core-shell nanowire. As we tune the time at which carriers are photogenerated during the acoustic cycle, we find pronounced intensity oscillations of neutral and negatively charged excitons. At high acoustic power levels these oscillations become anticorrelated which enables direct acoustic programming of the dot's charge configuration, emission intensity and emission wavelength. Numerical simulations confirm that the observed modulations arise from acoustically controlled modulations of the electron and electron-hole-pair concentrations at the position of the quantum dot.

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Section: Acoustic Control Of Qd Occupancy Statesupporting

confidence: 80%

Section: Sample and Optical Characterizationmentioning

confidence: 77%

Section: Dynamic Spectral Modulation and Saw Phase Calibrationmentioning

confidence: 99%

Section: Dynamic Spectral Modulation and Saw Phase Calibrationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Radio frequency occupancy state control of a single nanowire quantum dot

Weiß¹,

Schülein²,

Kinzel³

et al. 2014

J. Phys. D: Appl. Phys.

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Theory of semiconductor solid and hollow nano‐ and microwires with hexagonal cross‐section under torsion

Grundmann

2015

Physica Status Solidi (b)

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The effect of torsion on false[00.1false]‐oriented wurtzite and false[111false]‐oriented zincblende nanowires with hexagonal cross‐section is discussed. The stresses (and strains) are determined via calculation of Prantl's stress function. The spatial variation of the valence band structure in the cross‐section is evaluated in the framework of the 6×6 valence band Hamiltonian and deformation potential theory. The shear strain induced potential leads to additional localization of holes in the center of the facets. In wurtzite wires, torsion does not evoke piezoelectric charges or potentials and thus does not impact the signal in piezotronic sensors. In zincblende wires, the second order piezoelectric effect causes piezoelectric charges with threefold symmetry. The strain distribution in hexagonal nanowires with rounded corners depends on the curvature radius of the corners. For finite corner radius, the strain does no longer vanish at the corners. Also hexagonal nanotubes are discussed; here the inner and outer boundary exhibit different strain distributions. Visualization of the distribution of shear stress τ=σxz2+σyz2 in the hexagonal cross‐section of a false[00.1false]‐oriented wurtzite nanowire under torsion.

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Quantum Dot Optomechanics in Suspended Nanophononic Strings

et al. 2019

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The optomechanical coupling of quantum dots and flexural mechanical modes is studied in suspended nanophononic strings. The investigated devices are designed and monolithically fabricated on an (Al)GaAs heterostructure. Radio frequency elastic waves with frequencies ranging between f=250 and 400 MHz are generated as Rayleigh surface acoustic waves on the unpatterned substrate and injected as Lamb waves in the nanophononic string. Quantum dots inside the nanophononic string exhibit a 15‐fold enhanced optomechanical modulation compared to those dynamically strained by the Rayleigh surface acoustic wave. Detailed finite element simulations of the phononic mode spectrum of the nanophononic string confirm that the observed modulation arises from valence band deformation potential coupling via shear strain. The corresponding optomechanical coupling parameter is quantified to 0.15meVnnormalm−1. This value exceeds that reported for vibrating nanorods by approximately one order of magnitude at 100 times higher frequencies. Using this value, a derived vertical displacement in the range of 10 nm is deduced from the experimentally observed modulation. The results represent an important step toward the creation of large scale optomechanical circuits interfacing single optically active quantum dots with optical and mechanical waves.

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Dynamic Acoustic Control of Individual Optically Active Quantum Dot-like Emission Centers in Heterostructure Nanowires

Cited by 66 publications

References 56 publications

Radio frequency occupancy state control of a single nanowire quantum dot

Radio frequency occupancy state control of a single nanowire quantum dot

Theory of semiconductor solid and hollow nano‐ and microwires with hexagonal cross‐section under torsion

Quantum Dot Optomechanics in Suspended Nanophononic Strings

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