Optical Pumping of the Electronic and Nuclear Spin of Single Charge-Tunable Quantum Dots

Bracker, Allan S.; Stinaff, Eric; Gammon, D.; Ware, Morgan E.; Tischler, Joseph G.; Shabaev, A.; Éfros, Al. L.; Park, D.; Gershoni, D.; Korenev, V. L.; Merkulov, I. A.

doi:10.1103/physrevlett.94.047402

Cited by 319 publications

(317 citation statements)

References 30 publications

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“…Electron Overhauser shifts in excess of 100 μeV can be obtained using optical pumping [22][23][24][25]33,34 , and B nuc up to 3 T have been reported [23][24][25] . Using rough estimates of the dot composition, degrees of nuclear polarization up to 60% are now routinely obtained.…”

Section: Dynamic Nuclear Polarizationmentioning

confidence: 99%

“…However, there are a number of ways to overcome the energy mismatch and to induce a preferential pumping direction, both by optical and electrical means. There have been many attempts to find an efficient way of achieving DNP [21][22][23][24][25]33,34,49,52,53 , with the main motivation to achieve a 100% polarization of nuclear spins, which would prevent nuclear-nuclear flip-flops, strongly suppressing the randomness in the nuclear field and concomitant electron spin decoherence 10 .…”

Section: Dynamic Nuclear Polarizationmentioning

confidence: 99%

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Nuclear spin effects in semiconductor quantum dots

et al. 2013

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Section: Dynamic Nuclear Polarizationmentioning

confidence: 99%

Section: Dynamic Nuclear Polarizationmentioning

confidence: 99%

Nuclear spin effects in semiconductor quantum dots

et al. 2013

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“…7,8 At the same time, a fundamental question arises associated with the origin of so long-lived spin polarization. Along with suppression of main spin relaxation processes in QDs, predicted theoretically, 2 persistence of the spin polarization can result from dynamic nuclear polarization [10][11][12][13] capable to conserve the electron spin for a long time. It should be particularly emphasized that the dynamic nuclear polarization is a very slow process which cannot realize fast recording of information.…”

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confidence: 99%

Submillisecond electron spin relaxation in InP quantum dots

et al. 2005

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“…There, a dominant low-field contribution to spin depolarization curves was observed and was argued to arise from the resident electron left behind after recombination of negative trions. From low-temperature Hanle measurements of single QDs [13], there is evidence that the half-width of Hanle curves is significantly larger for positive trions than for negative trions, indicating a shorter spin lifetime for the former. However, detailed studies of the Hanle effect in positively charged QD ensembles remain few so far and are still lacking at temperatures close to RT.…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies of the Hanle effect in QDs were conducted at lower temperatures [13][14][15][16][17] and were mainly concentrated on characterization of negatively charged QDs. There, a dominant low-field contribution to spin depolarization curves was observed and was argued to arise from the resident electron left behind after recombination of negative trions.…”

Section: Introductionmentioning

confidence: 99%

The Hanle effect and electron spin polarization in InAs/GaAs quantum dots up to room temperature

et al. 2012

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Abstract. The Hanle effect in InAs/GaAs quantum dots (QDs) is studied under optical orientation as a function of temperature over the range of 150-300 K, with the aim to understand the physical mechanism responsible for the observed sharp increase of electron spin polarization with increasing temperature. The deduced spin lifetime T s of positive trions in the QDs is found to be independent of temperature, and is also insensitive to excitation energy and density. It is argued that the measured T s is mainly determined by the longitudinal spin flip time (T 1 ) and the spin dephasing time (T 2 * ) of the studied QD ensemble, of which both are temperature-independent over the studied temperature range and the latter makes a larger contribution. The observed sharply rising QD spin polarization degree with increasing temperature, on the other hand, is shown to be induced by an increase in spin injection efficiency from the barrier/wetting layer and also by a moderate increase in spin detection efficiency of the QD.PACS numbers: 73.21.La, 78.67.Hc, 72.25.Fe IntroductionSpins in semiconductor quantum dots (QDs) are the subject of extensive current research due to their weak interaction with the solid state environment, resulting in long spin lifetimes and the proposal for their application in spintronics and quantum information technology [1][2][3]. To this end, studies of spin injection and detection are important tasks to advance both our understanding of the relevant physical processes and to guide the design of improved structures for spintronic applications. Spin-related properties of QDs have in past years been investigated extensively, mainly at low temperatures, largely thanks to the availability of modern single-dot optical spectroscopy such as micro-photoluminescence (-PL) and scanning near-field optical microscopy (SNOM) [4][5][6][7][8][9][10]. Unfortunately, applications of these techniques for studies of QDs have been extremely restricted at elevated temperatures due to drastically decreasing emission intensity with increasing temperature. As a result, detailed studies and understanding of spin properties of QDs at temperatures close to room temperature (RT), highly relevant for practical applications, remain very limited.Recently, we reported a dramatic increase in electron spin polarization degree of InAs/GaAs QDs at high temperatures [11]. Polarization values up to 35% in the QD ground state at RT have been found, indicating at least equally high spin detection efficiency. In this work we carry out detailed studies of the Hanle effect [12], i.e. the depolarization effect in a transverse magnetic field, in InAs/GaAs QDs. Our aim is to determine the temperature dependence of the QD electron spin lifetime

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Optical Pumping of the Electronic and Nuclear Spin of Single Charge-Tunable Quantum Dots

Cited by 319 publications

References 30 publications

Nuclear spin effects in semiconductor quantum dots

Nuclear spin effects in semiconductor quantum dots

Submillisecond electron spin relaxation in InP quantum dots

The Hanle effect and electron spin polarization in InAs/GaAs quantum dots up to room temperature

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