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Electrical control of the sign of the g-factor in a GaAs hole quantum point contact

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 Added by Ashwin Srinivasan
 Publication date 2017
  fields Physics
and research's language is English




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Zeeman splitting of 1D hole subbands is investigated in quantum point contacts (QPCs) fabricated on a (311) oriented GaAs-AlGaAs heterostructure. Transport measurements can determine the magnitude of the g-factor, but cannot usually determine the sign. Here we use a combination of tilted fields and a unique off-diagonal element in the hole g-tensor to directly detect the sign of g*. We are able to tune not only the magnitude, but also the sign of the g-factor by electrical means, which is of interest for spintronics applications. Furthermore, we show theoretically that the resulting behavior of g* can be explained by the momentum dependence of the spin-orbit interaction.



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Single holes confined in semiconductor quantum dots are a promising platform for spin qubit technology, due to the electrical tunability of the $g$-factor of holes. However, the underlying mechanisms that enable electric spin control remain unclear due to the complexity of hole spin states. Here, we present an experimental and theoretical study of the $g$-factor of a single hole confined in an isotopically enriched silicon planar MOS quantum dot. Electrical characterisation of the 3x3 $g$-tensor shows that local electric fields can tune the g-factor by 500%, and we observe a sweet spot where d$g_{(1overline{1}0)}$/d$V$ = 0, offering a configuration to suppress spin decoherence caused by electrical noise. Numerical simulations show that unintentional electrode-induced strain plays a key role in mediating the coupling of hole spins to electric fields in these spin-qubit devices. These results open a path towards a previously unexplored technology; premeditated strain engineering for hole spin-qubits.
101 - V.K. Kalevich 2008
Positive signs of the effective g-factors for free electrons in the conduction band and electrons localized on deep paramagnetic centers have been measured in nitrogen dilute alloy GaAs{0.979}N{0.021} at room temperature. The g-factor signs have been determined from an asymmetry in the depolarization of edge photoluminescence in a transverse magnetic field (Hanle effect) at the oblique incidence of the exciting radiation and oblique-angle detection of the luminescence. The tilted spin polarization of free electrons is induced under interband absorption of circularly polarized light, and the paramagnetic centers acquire spin polarization because of spin-dependent capture of free spin-polarized electrons by these centers. The measured Hanle curve is a superposition of two lines, narrow and broad, with the widths ~400 G and ~50000 G, arising due to the depolarization of localized and free electrons, respectively. The magnitude and direction of the asymmetry in the measured Hanle curve have been found to depend on the partial contributions to the photoluminecsence from the heavy- and light-hole subbands split by a uniaxial deformation of the GaAs{1-x}N{x} film grown on a GaAs substrate. We have extended the theory of optical orientation in order to calculate the excitation spectrum of the photoelectron tilted-spin polarization and the circularly-polarized luminescence spectrum taking into account that, in the strained samples under study, the light-hole subband lies above the heavy-hole one. The results have further been used to calculate the shape of Hanle curve as a function of the excitation and registration energies as well as the incidence and detection angles and to compare the theory with experiment.
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