7 research outputs found
Strong electrically tunable exciton g-factors in an individual quantum dots due to hole orbital angular momentum quenching
Strong electrically tunable exciton g-factors are observed in individual
(Ga)InAs self-assembled quantum dots and the microscopic origin of the effect
is explained. Realistic eight band k.p simulations quantitatively account for
our observations, simultaneously reproducing the exciton transition energy, DC
Stark shift, diamagnetic shift and g-factor tunability for model dots with the
measured size and a comparatively low In-composition of x(In)~35% near the dot
apex. We show that the observed g-factor tunability is dominated by the hole,
the electron contributing only weakly. The electric field induced perturbation
of the hole wavefunction is shown to impact upon the g-factor via orbital
angular momentum quenching, the change of the In:Ga composition inside the
envelope function playing only a minor role. Our results provide design rules
for growing self-assembled quantum dots for electrical spin manipulation via
electrical g-factor modulation
Highly Non-linear Excitonic Zeeman Spin-Splitting in Composition-Engineered Artificial Atoms
Non-linear Zeeman splitting of neutral excitons is observed in composition
engineered In(x)Ga(1-x)As self-assembled quantum dots and its microscopic
origin is explained. Eight-band k.p simulations, performed using realistic dot
parameters extracted from cross-sectional scanning tunneling microscopy, reveal
that a quadratic contribution to the Zeeman energy originates from a spin
dependent mixing of heavy and light hole orbital states in the dot. The dilute
In-composition (x<0.35) and large lateral size (40-50 nm) of the quantum dots
investigated is shown to strongly enhance the non-linear excitonic Zeeman gap,
providing a blueprint to enhance such magnetic non-linearities via growth
engineering
Highly nonlinear excitonic Zeeman spin splitting in composition-engineered artificial atoms
Non-linear Zeeman splitting of neutral excitons is observed in composition engineerd InxGa1-xAS self-assembled quantum dots and its microscopic origin is explained. Eight-band k . p simulations, performed using realistic dot parameters extracted from cross-sectional scanning tunneling microscopy, reveal that a quadratic contribution to the Zeeman energy originates from a spin dependent mixing of heavy and light hole orbital states in the dot. The dilute In-composition (x 0.35) and large lateral size (40 - 50 nm) of the quantum dots investigated is shown to strongly enhance the non-linear excitonic Zeeman gap, providing a blueprint to enhance such magnetic non-linearitics via growth engineerin