443 research outputs found
Magneto-capacitance probing of the many-particle states in InAs dots
We use frequency-dependent capacitance-voltage spectroscopy to measure the
tunneling probability into self-assembled InAs quantum dots. Using an in-plane
magnetic field of variable strength and orientation, we are able to obtain
information on the quasi-particle wave functions in momentum space for 1 to 6
electrons per dot. For the lowest two energy states, we find a good agreement
with Gaussian functions for a harmonic potential. The high energy orbitals
exhibit signatures of anisotropic confinement and correlation effects.Comment: 3 pages, 3 figure
Split-gate quantum point contacts with tunable channel length
We report on developing split-gate quantum point contacts (QPCs) that have a
tunable length for the transport channel. The QPCs were realized in a
GaAs/AlGaAs heterostructure with a two- dimensional electron gas (2DEG) below
its surface. The conventional design uses 2 gate fingers on the wafer surface
which deplete the 2DEG underneath when a negative gate voltage is applied, and
this allows for tuning the width of the QPC channel. Our design has 6 gate
fingers and this provides additional control over the form of the electrostatic
potential that defines the channel. Our study is based on electrostatic
simulations and experiments and the results show that we developed QPCs where
the effective channel length can be tuned from about 200 nm to 600 nm.
Length-tunable QPCs are important for studies of electron many-body effects
because these phenomena show a nanoscale dependence on the dimensions of the
QPC channel
Transform-limited single photons from a single quantum dot
A semiconductor quantum dot mimics a two-level atom. Performance as a single
photon source is limited by decoherence and dephasing of the optical
transition. Even with high quality material at low temperature, the optical
linewidths are a factor of two larger than the transform-limit. A major
contributor to the inhomogeneous linewdith is the nuclear spin noise. We show
here that the nuclear spin noise depends on optical excitation, increasing
(decreasing) with increasing resonant laser power for the neutral (charged)
exciton. Based on this observation, we discover regimes where we demonstrate
transform-limited linewidths on both neutral and charged excitons even when the
measurement is performed very slowly
Epitaxial lift-off for solid-state cavity quantum electrodynamics
We present a new approach to incorporate self-assembled quantum dots into a
Fabry-P\'{e}rot-like microcavity. Thereby a 3/4 GaAs layer containing
quantum dots is epitaxially removed and attached by van der Waals bonding to
one of the microcavity mirrors. We reach a finesse as high as 4,100 with this
configuration limited by the reflectivity of the dielectric mirrors and not by
scattering at the semiconductor - mirror interface, demonstrating that the
epitaxial lift-off procedure is a promising procedure for cavity quantum
electrodynamics in the solid state. As a first step in this direction, we
demonstrate a clear cavity-quantum dot interaction in the weak coupling regime
with a Purcell factor in the order of 3. Estimations of the coupling strength
via the Purcell factor suggests that we are close to the strong coupling
regime.Comment: 6 pages, 4 figure
Spin coherence of holes in GaAs/AlGaAs quantum wells
The carrier spin coherence in a p-doped GaAs/(Al,Ga)As quantum well with a
diluted hole gas has been studied by picosecond pump-probe Kerr rotation with
an in-plane magnetic field. For resonant optical excitation of the positively
charged exciton the spin precession shows two types of oscillations. Fast
oscillating electron spin beats decay with the radiative lifetime of the
charged exciton of 50 ps. Long lived spin coherence of the holes with dephasing
times up to 650 ps. The spin dephasing time as well as the in-plane hole g
factor show strong temperature dependence, underlining the importance of hole
localization at cryogenic temperatures.Comment: 5 pages, 4 figures in PostScript forma
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