Anisotropy of electron and hole<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mi>g</mml:mi></mml:math>tensors of quantum dots: An intuitive picture based on spin-correlated orbital currents

Bree, van J Joost; Silov, AY Andrei; Maasakkers, van Ml; Pryor, Craig; Flatté, Michael E.; Koenraad, PM Paul

doi:10.1103/physrevb.93.035311

Cited by 26 publications

(42 citation statements)

References 51 publications

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“…and P h,x−z = (g h,x − g h,z )/(g h,x + g h,z ) = (88.55 ± 0.02)%, as shown in Tables I. This can be ascribed to the anisotropic QD shape leading to the different spatial real-space wave function distributions and the non-zero orbital momenta carried by hole states [53][54][55].…”

Section: Energymentioning

confidence: 88%

Electron and Hole g Tensors of Neutral and Charged Excitons in Single Quantum Dots by High-Resolution Photocurrent Spectroscopy

Peng

Xie

et al. 2020

Phys. Rev. Applied

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We report a high-resolution photocurrent (PC) spectroscopy of a single self-assembled InAs/GaAs quantum dot (QD) embedded in an n-i-Schottky device with an applied vector magnetic field. The PC spectra of positively charged exciton (X +) and neutral exciton (X 0) are obtained by two-color resonant excitation. With an applied magnetic field in Voigt geometry, the double Λ energy level structure of X + and the dark states of X 0 are observed in PC spectra clearly. In Faraday geometry, the PC amplitude of X + decreases and then quenches with the increasing of the magnetic field, which provides a new way to determine the relative sign of the electron and the hole g-factors. With an applied vector magnetic field, the electron and the hole g-factor tensors of X + and X 0 are obtained. The anisotropy of the hole g-factors of both X + and X 0 is larger than that of the electron.

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Section: Energymentioning

confidence: 88%

Electron and Hole g Tensors of Neutral and Charged Excitons in Single Quantum Dots by High-Resolution Photocurrent Spectroscopy

Peng

Xie

et al. 2020

Phys. Rev. Applied

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“…39 Improvements can be expected from an extended model that also involves the split-off band and the conduction band. 34,43,44 Finally, although our assumption of an infinite HW with a rectangular cross-section is a reasonable approximation for the elongated HW QDs realized here, the details of the confinement (and the strain) along all spatial directions can provide additional corrections. Taking all these elements fully into account is beyond the scope of the present work and requires extensive numerics.…”

mentioning

confidence: 96%

Heavy-Hole States in Germanium Hut Wires

et al. 2016

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Hole spins have gained considerable interest in the past few years due to their potential for fast electrically controlled qubits. Here, we study holes confined in Ge hut wires, a so-far unexplored type of nanostructure. Low-temperature magnetotransport measurements reveal a large anisotropy between the in-plane and out-of-plane g-factors of up to 18. Numerical simulations verify that this large anisotropy originates from a confined wave function of heavy-hole character. A light-hole admixture of less than 1% is estimated for the states of lowest energy, leading to a surprisingly large reduction of the out-of-plane g-factors compared with those for pure heavy holes. Given this tiny light-hole contribution, the spin lifetimes are expected to be very long, even in isotopically nonpurified samples.

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“…The hole hyperfine constant in the (111) quantum dots is sensitive to the dot geometry through the light-heavy-hole mixing. This opens the way for engineering the hole-nuclear spin interaction [23,41]. The main route to control the effective heavy-hole hyperfine constant C eff in (111) quantum dots, given by Eq.…”

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confidence: 99%

Hyperfine coupling of hole and nuclear spins in symmetric (111)-grown GaAs quantum dots

et al. 2016

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In self-assembled III-V semiconductor quantum dots, valence holes have longer spin coherence times than the conduction electrons, due to their weaker coupling to nuclear spin bath fluctuations. Prolonging hole spin stability relies on a better understanding of the hole to nuclear spin hyperfine coupling which we address both in experiment and theory in the symmetric (111) GaAs/AlGaAs droplet dots. In magnetic fields applied along the growth axis, we create a strong nuclear spin polarization detected through the positively charged trion X + Zeeman and Overhauser splittings. The observation of four clearly resolved photoluminescence lines-a unique property of the (111) nanosystems-allows us to measure separately the electron and hole contribution to the Overhauser shift. The hyperfine interaction for holes is found to be about five times weaker than that for electrons. Our theory shows that this ratio depends not only on intrinsic material properties but also on the dot shape and carrier confinement through the heavy-hole mixing, an opportunity for engineering the hole-nuclear spin interaction by tuning dot size and shape.

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Anisotropy of electron and holegtensors of quantum dots: An intuitive picture based on spin-correlated orbital currents

Cited by 26 publications

References 51 publications

Electron and Hole g Tensors of Neutral and Charged Excitons in Single Quantum Dots by High-Resolution Photocurrent Spectroscopy

Electron and Hole g Tensors of Neutral and Charged Excitons in Single Quantum Dots by High-Resolution Photocurrent Spectroscopy

Heavy-Hole States in Germanium Hut Wires

Hyperfine coupling of hole and nuclear spins in symmetric (111)-grown GaAs quantum dots

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