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Topological insulators belong to a new quantum state of matter that is currently one of
the most recognized research fields in condensed matter physics. Strained bulk HgTe
and HgTe/HgCdTe quantum well structures are currently one of few topological insulator
material systems suitable to be studied in transport experiments. In addition
HgTe quantum wells provide excellent requirements for the conduction of spintronic
experiments. A fundamental requirement for most experiments, however, is to reliably
pattern these heterostructures into advanced nano-devices. Nano-lithography on this
material system proves to be challenging because of inherent temperature limitations,
its high reactivity with various metals and due to its properties as a topological insulator.
The current work gives an insight into why many established semiconductor
lithography processes cannot be easily transferred to HgTe while providing alternative
solutions. The presented developments include novel ohmic contacts, the prevention
of metal sidewalls and redeposition fences in combination with low temperature
(80 °C) lithography and an adapted hardmask lithography process utilizing a sacrificial
layer. In addition we demonstrate high resolution low energy (2.5 kV) electron beam
lithography and present an alternative airbridge gating technique. The feasibility of
nano-structures on HgTe quantum wells is exemplarily verified in two separate transport
experiments. We are first to realize physically etched quantum point contacts
in HgTe/HgCdTe high mobility 2DEGs and to prove their controllability via external
top-gate electrodes. So far quantum point contacts have not been reported in TI
materials. However, these constrictions are part of many proposals to probe the nature
of the helical quantum spin Hall edge channels and are suggested as injector and
detector devices for spin polarized currents. To confirm their functionality we performed
four-terminal measurements of the point contact conductance as a function of
external gate voltage. Our measurements clearly exhibit quantized conductance steps
in 2e2/h, which is a fundamental characteristic of quantum point contacts. Furthermore
we conducted measurements on the formation and control of collimated electron beams, a key feature to realize an all electrical spin-optic device. In a second study
several of the newly developed lithography techniques were implemented to produce
arrays of nano-wires on inverted and non-inverted HgTe quantum well samples. These
devices were used in order to probe and compare the weak antilocalization (WAL) in
these structures as a function of magnetic field and temperature. Our measurements
reveal that the WAL is almost an order of magnitude larger in inverted samples. This
observation is attributed to the Dirac-like dispersion of the energy bands in HgTe quantum
wells. The described lithography has already been successfully implemented and
adapted in several published studies. All processes have been optimized to guarantee
a minimum effect on the heterostructure’s properties and the sample surface, which is
especially important for probing the topological surface states of strained HgTe bulk
layers. Our developments therefore serve as a base for continuous progress to further
establish HgTe as a topological insulator and give access to new experiments.
This doctoral thesis investigates magneto-optical properties of mercury telluride layers grown tensile strained on cadmium telluride substrates. Here, layer thicknesses start above the usual quantum well thickness of about 20 nm and have a upper boundary around 100 nm due to lattice relaxation effects. This kind of layer system has been attributed to the material class of three-dimensional topological insulators in numerous publications. This class stands out due to intrinsic boundary states which cross the energetic band gap of the layer's bulk.
In order to investigate the band structure properties in a narrow region around the Fermi edge, including possible boundary states, the method of highly precise time-domain Terahertz polarimetry is used. In the beginning, the state of the art of Teraherz technology at the start of this project is discussed, moving on to a detailed description and characterization of the self-built measurement setup. Typical standard deviation of a polarization rotation or ellipticity measurement are on the order of 10 to 100 millidegrees, according to the transmission strength through investigated samples. A range of polarization spectra, depending on external magnetic fields up to 10 Tesla, can be extracted from the time-domain signal via Fourier transformation.
The identification of the actual band structure is done by modeling possible band structures by means of the envelope function approximation within the framework of the k·p method. First the bands are calculated based on well-established model parameters and from them the possible optical transitions and expected ellipticity spectra, all depending on external magnetic fields and the layer's charge carrier concentration. By comparing expected with measured spectra, the validity of k·p models with varying depths of detail is analyzed throughout this thesis. The rich information encoded in the ellipitcity spectra delivers key information for the attribution of single optical transitions, which are not part of pure absorption spectroscopy. For example, the sign of the ellipticity signals is linked to the mix of Landau levels which contribute to an optical transition, which shows direct evidence for bulk inversion asymmetry effects in the measured spectra.
Throughout the thesis, the results are compared repeatedly with existing publications on the topic. It is shown that the models used there are often insufficient or, in worst case, plainly incorrect. Wherever meaningful and possible without greater detours, the differences to the conclusions that can be drawn from the k·p model are discussed.
The analysis ends with a detailed look on remaining differences between model and measurement. It contains the quality of model parameters as well as different approaches to integrate electrostatic potentials that exist in the structures into the model.
An outlook on possible future developments of the mercury cadmium telluride layer systems, as well as the application of the methods shown here onto further research questions concludes the thesis.
Exploring the transport properties of the three-dimensional topological insulator material HgTe
(2015)
In the present thesis the transport properties of strained bulk HgTe devices are investigated. Strained HgTe forms a 3D TI and is of special interest for studying topological surface states, since it can be grown by MBE in high crystal quality. The low defect density leads to considerable mobility values, well above the mobilities of other TI materials. However, strained HgTe has a small band gap of ca. 20 meV. With respect to possible applications the question is important, under which conditions the surface transport occurs. To answer this question, the HgTe devices are investigated at dilution refrigerator temperatures (T<100 mK) in high magnetic fields of different orientation. The influence of top and back gate electrodes as well as surface protecting layers is discussed.
On the basis of an analysis of the quantum Hall behaviour it is shown that transport is dominated by the topological surface states in a surprisingly large parameter range. A dependence on the applied top gate voltage is presented for the topological surface states. It enables the first demonstration of an odd integer QHE sequence from the surfaces perpendicular to the magnetic field. Furthermore, the p-type QHE from the surface states is observed for the first time in any 3D TI. This is achieved in samples of high surface quality. It is concluded from the gate response that the screening behaviour in 3D TI devices is non-trivial. The transport data are qualitatively analysed by means of intuitive theoretical models.