Real-Time Detection of Single Auger Recombination Events in a Self-Assembled Quantum Dot

Lochner, Pia; Kurzmann, Annika; Kerski, Jens; Stegmann, Philipp; König, Jürgen; Wieck, A. D.; Ludwig, Arne; Lorke, Axel; Geller, M.

doi:10.1021/acs.nanolett.9b04650

Cited by 18 publications

(16 citation statements)

References 40 publications

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“…The QD layer is embedded in a p-i-n diode structure with a highly n-doped GaAs layer as a charge reservoir and a highly p-doped GaAs layer as an epitaxial gate 34 . Between the charge reservoir and the QD, 45 nm (AlGa)As are implemented as tunneling barrier to achieve electron tunneling times in the order of milliseconds (see Lochner et al 28 for details about the sample structure). An applied voltage between charge reservoir and gate can control the charge state of the QD.…”

Section: Sample Design and Methodsmentioning

confidence: 99%

“…This scattering process is well known from colloidal QDs [22][23][24] and has been directly observed just recently in resonance fluorescence measurements 25 with Auger recombination rates in the order of microseconds. [26][27][28][29] In this paper, we show time-resolved resonance fluorescence (RF) measurements on the trion transitions of a a) Electronic mail: hendrik.mannel@uni-due.de negatively-charged InAs QD, embedded in an electrically controllable diode structure and charged by electron tunneling from a nearby charge reservoir. An applied magnetic field B of up to 10 T in Faraday geometry (here, parallel to the growth axis) splits the trion into a lower ("red") and a higher ("blue") energy transition.…”

Section: Introductionmentioning

confidence: 99%

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Auger and spin dynamics in a self-assembled quantum dot

Mannel¹,

Kerski²,

Lochner³

et al. 2021

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The Zeeman-split spin states of a single quantum dot can be used together with its optical trion transitions to form a spin-photon interface between a stationary (the spin) and a flying (the photon) quantum bit. Besides long coherence times of the spin state itself, the limiting decoherence mechanisms of the trion states are of central importance. We investigate here in time-resolved resonance fluorescence the electron and trion dynamics in a single self-assembled quantum dot in an applied magnetic field of up to B = 10 T. The quantum dot is only weakly coupled to an electron reservoir with tunneling rates of about 1 ms −1 . Using this sample structure, we can measure, in addition to the spin-flip rate of the electron and the spin-flip Raman rate of the trion transition, the Auger recombination process, that scatters an Auger electron into the conduction band. The Auger effect destroys the radiative trion transition and leaves the quantum dot empty until an electron tunnels from the reservoir into the dot. The Auger recombination rate decreases by a factor of three from γ A = 3 µs −1 down to 1 µs −1 in an applied magnetic field of 10 T in Faraday geometry. The combination of an Auger recombination event with subsequent electron tunneling from the reservoir can flip the electron spin and thus constitutes a previously unaccounted mechanism that limits spin coherence, an important resource for quantum technologies.

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Section: Sample Design and Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Auger and spin dynamics in a self-assembled quantum dot

Mannel¹,

Kerski²,

Lochner³

et al. 2021

Preprint

Self Cite

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show abstract

“…bedded in a p-i-n diode structure (see Fig. 1(a), (b) and [16] for more details). The n + -doped back contact serves as an electron reservoir, separated from the QD by a tunnel barrier of 30 nm GaAs, 10 nm Al 0.33 Ga 0.67 As and 5 nm GaAs.…”

Section: Methodsmentioning

confidence: 99%

“…For example, timeresolved photoluminescence can be used to study charge * jens.kerski@uni-due.de fluctuations in colloidal nanocrystals at room temperature [13,14]. Also, resonant fluorescence at compared to the mK scale high temperatures (4.2 K) can be used to study tunneling [15] and Auger processes [16] in selfassembled quantum dots (QDs) as well as spin dynamics [17] in quantum dot molecules. The optical excitation of the single quantum emitter by resonant fluorescence offers a high energetic resolution, and the detection of the single photons with avalanche photodiodes or superconducting nanowire detectors promises a high bandwidth.…”

Section: Introductionmentioning

confidence: 99%

Post-processing of real-time quantum event measurements for an optimal bandwidth

Kerski¹,

Mannel²,

Lochner³

et al. 2021

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“…Auger recombination is a non-radiative process in which the energy released during electron and hole recombination is transferred to a third charge carrier (either electron or hole) which is then excited to a higher energy state. [23][24][25] Alternatively, it has been shown that multiple electrons can be transferred from photoexcited QDs to different molecular acceptors, e.g. methylene blue (MB).…”

Section: Introductionmentioning

confidence: 99%