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Towards a THz Bloch laser
(2011)
The realisation of tunable THz laser sources working at room temperature would give
rise to further applications in this range of the electromagnetic spectrum. The THz
Bloch laser could therefore become the basis for a technological breakthrough. Beside
this practical relevance, the physics of the gain mechanism has been investigated
theoretically for a long time and the experimental implementation of a self-starting
laser still has not been achieved.
At the beginning of this thesis the basic principles of Bloch oscillations and the
related Bloch gain are described. The need of a superlattice structure to make Bloch
oscillations possible in a semiconductor material is discussed. In this context, the effect
of negative differential resistance and its influence on the field distribution due to Gunn
domains is explained. The latter lead to an inhomogeneous field which may suppress
the Bloch gain mechanism. The Krömer criterion is introduced and the concept of
field-pinning layers to improve the field homogeneity is deduced. Finally, the design of
the laser material is shown and different types of laser waveguides are compared.
In chapter 3 detailed recipes for the processing of samples are given. Different types of
contacts (ohmic and Schottky), the wafer bonding process required for double-metal
lasers and the application of different photoresists for different purposes are described.
An explanation of the formation of waveguides due to dry etching, wet etching
and ion implantation follows. Dry etching is an established technique in the field
of microstructure processing but the challenge of etching about 20 μm has led to
problems. The high etching depth also makes wet etching difficult but this method
could be improved due to a hard bake of the photoresist. The protection of critical
areas on the surface of the samples with photoresist during ion implantation was
increased by optimising the spin coating process. However, a full implantation of the
active layer between the waveguides was not achieved which was the reason for the
development of the hybrid technology. Here a prior wet etching of about 10 μm is
performed and the rest of the material is implanted.
The experimental setup is shown in chapter 4. An alternative method for the electrical
contacting with the help of a copper bar is introduced. This improves the current
distribution and the risk of an electrical breakdown during the measurements could
therefore be lowered. Devices for THz beam guidance and spectroscopic measurements
are shown and the method of biasing the samples with pulses below 100 ns and
determining the effective voltage applied to the sample is depicted. These short pulses
are required to prevent the samples heating up drastically due to high power.
Chapter 5 contains the current-voltage characterisation of several structures including
I-V-samples, Bloch laser samples and a quantum cascade laser. Different contacts
(ohmic and Schottky) and different techniques for the formation of the ridges have
been used in the processing of these samples (performed at the University of Frankfurt
in all cases) and their influence on the I-V-dependence is discussed. The properties of
the THz emission of the quantum cascade laser are in good agreement with published
results from lasers processed with the same material. Another important result of
this chapter is that the Bloch laser samples show unstable behaviour compared to the
quantum cascade structure even with short pulses (of about 10 ns) where the risk of an
electrical breakdown or the building of filaments is low. THz radiation emitted from
one of the Bloch laser samples could not be observed.
Two aspects that may have prevented the Bloch laser to emit are discussed in
chapter 6. The saturation of the gain for higher amplitudes of the THz wave is
investigated in single mode and multiple mode operation (the latter could occur due
to the Bloch gain being expected to be broadband). In both cases it is shown that
the saturation effect would limit the output power only to values clearly above the
detection limit. In the subsequent section the distribution of the electric field is
simulated with SILVACO software. Structures with transit layer lengths above the
Krömer criterion are compared with structures which include field-pinning layers. It is
shown that the latter are useful to avoid propagating Gunn domains as they build up
in similar structures without field-pinning layers. Nevertheless, the electric field inside
the superlattice regions is not stable. Beside spatial inhomogeneities also temporal
variations of the field magnitude are observed. The lack of a suitable field distribution
is expected to be the main reason for the samples not to work.
In the field of strongly correlated electron systems, there is a long standing discussion on whether lattice degrees of freedom play a role for several physical phenomena, among them the Mott MI transition and charge-ordering transition. Charge-transfer salts of the ..-(BEDT-TTF)2X and (TMTCF)2X families have been revealed as model systemss for the study of the latter phenomena. The (TMTCF)2X salts have been recognized as model systems for studying correlation effects in 1D, while the (BEDT-TTF)-based materials for such studies in 2D. In this work, high-resolution dilatometry experiments were performed in order to address these issues. The main results obtained are summarized below. ...
Magnetic characteristics of metal organic low-dimensional quantum spin systems at low temperatures
(2010)
In dieser Arbeit wurden neue Klassen von niedrigdimensionalen metallisch-organischen Materialien untersucht, die es ermöglichen interessante quantenkritische Phänomene (quantum critical phenomena, QCP) wie die Bose-Einstein-Kondensation (Bose-Einstein condensation, BEC) der magnetischen Anregung in gekoppelten Spin-Dimer-Systemen, den Berezinskii-Kosterlitz-Thouless Übergang (Berezinskii-Kosterlitz-Thouless transition, BKT) und die Divergenz des magnetokalorischen Effekts (magnetocaloric effect, MCE) in Quanten-Spinsystemen beim Anlegen eines magnetischen Feldes zu beobachten. Die Niedrigdimensionalität der untersuchten Systeme war sowohl für die theoretische Beschreibung, als auch für die experimentelle Beobachtung der Phänomene von großer Bedeutung. Aus theoretischer Sicht eröffnet die Beschäftigung mit diesen Systemen die Möglichkeit, einfache Modelle zu entwickeln, die exakt lösbar sind und erlaubt somit ein qualitatives Verständnis der magnetischen Phänomene. Von experimenteller Seite ist es von größtem Interesse, dass durch das Zusammenspiel von Niedrigdimensionalität, konkurrierenden Wechselwirkungen und starker Quantenfluktuation exotische und aufregende magnetische Phänomene (quantenkritische Phänomene) entstehen, die mit verschiedenen experimentellen Methoden untersucht werden können. Um die intrinsischen Eigenschaften der quantenkritischen Phänomene zu verstehen ist es wichtig, die Phänomene an einfachen und gut kontrollierbaren niedrigdimensionalen Modellsystemen wie ein- oder zweidimensionalen Systemen zu untersuchen. ...
In der modernen Festkörperphysik spielen elektronisch stark korrelierte Systeme mit ihrem komplexen Vielteilchenverhalten eine zentrale Rolle. Insbesondere das Wechselspiel zwischen thermischen und Quantenfluktuationen in den Ladungs- und Spinfreiheitsgraden führt zur Entstehung verschiedenster neuartiger Grundzustände.
Die vorliegende Dissertation „Ultrasonic and Magnetic Investigations in frustrated Lowdimensional Spin Systems“ beschäftigt sich mit den besonderen physikalischen Eigenschaften niedrig dimensionaler Spinsysteme. Diese Materialklasse, die auch zu den stark korrelierten Systemen zählt, wird seit vielen Jahren intensiv sowohl experimentell als auch theoretisch untersucht. Auf theoretischer Seite sind die niedrigdimensionalen Spinsysteme besonders interessant, da sie als Modellsysteme die exakte Beschreibung des Grundzustandes und des Anregungsspektrums ermöglichen. Von experimenteller Seite ist es in den letzten Jahrzehnten gelungen, verschiedenste Materialklassen niedrigdimensionaler Spinsysteme zu synthetisieren.
In der vorliegenden Arbeit werden die grundlegenden Theorien und physikalischen Konzepte niedrigdimensionaler Spinsysteme diskutiert. Insbesondere auch die Spin-Phonon-Wechselwirkung dieser Materialien, die für die hier beobachteten elastischen Anomalien verantwortlich ist. Weiterhin wird auch das elastische Verhalten bei magnetischen Phasenübergängen beschrieben.
Da die Ultraschallexperimente einen Schwerpunkt dieser Arbeit bilden, wird der Versuchsaufbau zur phasenempfindlichen Detektion von Schallgeschwindigkeit und Ultraschalldämfung ausführlich beschrieben. Diese Messmethode ist ideal zur Untersuchung der Spin-Phonon Wechselwirkung geeignet.
In this thesis we report on the high pressure synthesis, crystal growth, structural characterisation and magnetic properties of the cubic vanadate pyrochlores A2V2O7 (with A = Y, Er and Dy). We have found that high pressure is requisite for the stabilization of the selected compounds. For this purpose, a multianvil high pressure apparatus was built in our laboratory and a new multianvil inset (i.e., a ceramic pressure medium and the interior parts) was developed. The multianvil press is based on a hydraulic press with a maximum force of 7.73 MN (corresponds to 788 tons), a Walker type module and a specially designed hydraulic and electric control. Pressure calibration of the multianvil setup was performed by high pressure fixed points (i.e. solid-solid transformation of Bi I-II (2.55 GPa) and Bi II-III (3.15 GPa)). A maximum pressure of 6 GPa was attained using hardened metal anvils (tungsten carbide) with truncation edge length (TEL) of 14 mm and a sample volume of ~ 70 mm3. Heating of the sample in our current multianvil setup (TEL = 14 mm) was achieved by resistive heating of a graphite furnace. Temperatures up to 1500 °C could be obtained at pressures up to 6 GPa. By systematic variation of the synthesis conditions (for instance the operation temperature or the choice of the crucible material) under high pressure and taking into account the well known ternary compounds, when accessing the phase diagram, the cubic vanadate pyrochlores A2V2O7 (with A = Y, Er and Dy) were synthesized successfully. It was found that the oxygen partial pressure is crucial for the formation of the desired pyrochlore phase. Gas-tight platinum crucibles were used as container material for the synthesis of the vanadate pyrochlores. We have investigated, that pressures of the order of 5.0 GPa and temperatures of approximately 1200 °C are necessary for the stabilization of the monophasic samples of the vanadate pyrochlores. Lu2V2O7 could be synthesized under ambient pressure conditions and is used in our studies for comparison purposes. A special graphite furnace was developed for the high pressure crystal growth of the vanadate pyrochlores. For the first time, A2V2O7 (with A = Y, Er and Dy) single crystals with a maximum size of 0.4 mm were grown by using the grain growth method at high pressure and high temperature conditions. The samples (i.e., powders and single crystals) were characterised by single crystal Xray diffraction, X-ray powder diffraction method, Laue method and scanning electron microscopy (SEM). Complementary to the X-ray diffraction methods, infrared absorsoption spectroscopy was used to distinguish between the fluorite and pyrochlore structure. It has been shown that all samples crystallize in a well-ordered cubic structure with the space group F d 3m. The vanadium (+4) content in the samples was determined by oxidative weight gain in air using a thermogravimetric (TG) balance. A structural phase transformation of cubic to tetragonal was observed by differential thermal analysis (DTA) in conjunction with high temperature diffractometry. The magnetic characterisation of the vanadate pyrochlores A2V2O7 (Y, Lu, Er and Dy) was performed by Katarina Removic-Langer in the laboratory of Prof. Dr. M. Lang. All materials studied are ferromagnetic. The ferromagnetic critical temperatures are between 70 and 73 K. In case of Er2V2O7 and Dy2V2O7 an additional increase in the magnetization was observed below 20 K. The increase in the magnetization below 20 K exhibited by Er2V2O7 and Dy2V2O7 originates from the interactions between the two magnetic sublattices (i.e., the rare earth- and the vanadium sublattice).