Abschlussarbeiten
Inhaltsverzeichnis
Ferroix group:
Cherenkov second harmonic microscopy characterization of multiaxial ferroelectrics
Throughout the last years, Cherenkov second harmonic microscopy (CSHG) has been successfully applied in our group for the three-dimensional position tracking of domain walls (DWs) in uniaxial ferroelectrics such as lithium niobate (LiNbO3). Within this project, this approach shall be extended to multiaxial materials such as BaTiO3 and KNbO3. Thereby, we do not only aim at obtaining the DW position information, but moreover at a deeper understanding of the process of SHG at DWs by analyzing the intensity and polarization dependencies.
Research team: FERROIX
Contact: Prof. Lukas M. Eng
Type: BA, MA
Domain wall conductivity measurements of stochastic domain patterns in lithium niobate
The transport behavior of ferroelectric domain walls (DWs) in LiNbO3 (LNO) single crystals has been extensively studied in our group for the case of single domains that were specifically written for this purpose. However, it is likewise possible to generate a stochastic multi-domain structure in such crystals by applying a homogeneous electric field to a large (~mm²) sample area. Here, we wish to quantify the variance in conductivity of these as-grown DWs by evaporating a microstructured electrode and measuring I-V-curves between the individual electrode fields.
Research team: FERROIX
Contact: Prof. Lukas Eng
Type: BA, MA
SKY group:
Skyrmionen in Defektspinellen
Ziel der Masterarbeit ist die präzise Vermessung des magnetischen Phasendiagramms von GaV4S8 bei Temperaturen unterhalb von 10K mit Hilfe des Tieftemperatur-Rasterkraftmikroskopes. Zu diesem Zweck ist ein spezieller Probenhalter mit einem Widerstandsthermometer auszurüsten, so dass sowohl die magnetische Flussdichte als auch die Temperatur der Probe exakt bestimmt werden können. Von besonderem Interesse sind die Bestimmung möglicher Anharmonizitäten in der zykloidalen Phase und der Phasenübergang von der Skyrmiongitterphase zur kollinearen Phase.
Arbeitsgruppe: SKY
Kontakt: Dr. Peter Milde
geeignet für: MA
Skyrmionen in elektrischen Feldern
Cu2OSeO3 ist ein helimagnetischer Isolator, in dem Skyrmionen bei ca. 57K beobachtet werden können. Aufgrund magnetoelektrischer Kopplungseffekte kann die Skyrmionenphase durch Anlegen elektrischer Felder beeinflusst werden. Ziel der Arbeit ist es den Einfluss elektrischer Felder auf die Ausbildung der Skyrmionenphase zu studieren und Veränderungen der Skyrmionentextur im Ortsraum aufgelöst zu beobachten. Alle Experimente werden am Tieftemperatur-Rasterkraftmikroskop durchgeführt.
Arbeitsgruppe: SKY
Kontakt: Dr. Peter Milde
geeignet für: MA
Superheterodynes Interferometer
Im Tieftemperatur-Rasterkraftmikroskop wird die Auslenkung eines Federbalkens mit Hilfe eines Interferometers gemessen. Für die Komplettierung eines upgrades auf ein heterodyn arbeitendes Interferometer ist der Aufbau einer elektronischen Schaltung zur Messung der Phasenänderung des Detektionslichtpfades erforderlich. Die Arbeit richtet sich vornehmlich an Studenten mit Erfahrung im und Freude am Aufbau von elektronischen Hochfrequenzschaltungen (inklusive Design der Platinen in eagle).
Arbeitsgruppe: SKY
Kontakt: Dr. Peter Milde
geeignet für: BA, MA
SNOM group:
High-resolution probing in the mid-IR to THz spectral regime
Scattering scanning near-field optical microscopy (SNOM) enables the nanoscopic optical examination of sample surfaces with a wavelength-independent resolution of few 10 nanometers. Particularly in the IR-to-THz regime, materials show a strong response to electro-magnetic radiation due to excitation of lattice vibrations, chemical bonds, and charge carrier oscillations. Probing such responses on the local scale enables unique scientific characterization of modern materials and nanostructured devices, which shall be studied in this work.
This thesis includes working with optics in the visible, infrared, and THz regime with unique light sources (state-of-the-art table top lasers and free-electron laser at HZDR) and understanding fundamental optical material response on the nanoscopic scale.
This work is particularly suitable to be followed by a PhD thesis.
[Tags: IR-/THz-optics, lasers, free-electron laser, SNOM, scanning probe microscopy, nanoooptics]
Arbeitsgruppe: SNOM
Kontakt: Susanne C. Kehr
geeignet für: MA/PhD
Nanoscopic infrared characterization of structured van-der-Waals-materials
The infrared optical response of matter is determined by fundamental material parameters such as lattice vibrations, chemical bonds, and charge carrier oscillations. Here, 2-dimensional (2D)- and van der Waals (vdW) materials characteristically show a strongly anisotropic response that even reaches hyperbolic behavior, which lead to intriguing effects such as unidirection propagation and high confinement of THz fields that are urgently wanted for nanotechnological applications. In this work, the roles of geometrical and excitation parameters shall be studied for a range of materials such as MoO3, GeS, and hBN and utilized to tailor the materials’ response and to design optical devices for THz applications.
This thesis includes working with optics in the infrared to THz regime including near-field (high-resolution) probing along with various scanning probe techniques, sample preparation and modelling of material responses.
This work is particularly suitable to be followed by a PhD thesis.
[Tags: Nanooptics, nanotechnology, SNOM, AFM, Laser, IR-Optics]
Arbeitsgruppe: SNOM
Kontakt: Susanne C. Kehr
geeignet für: MA/PhD
Nanometer-scale investigations at low temperatures
In many material systems, properties such as optical response, conductivity and/or work function change drastically at low temperatures. Combining different scanning probe techniques including atomic force microscopy (AFM), conductive-AFM (c-AFM), Kelvin-probe force microscopy (KPFM) and scattering scanning near-field optical microscopy (s-SNOM), this response can be measured on the local scale with a lateral resolution on the nanometer length scale, which enables the fundamental understanding of the material properties. With our setup, all of these measurements can be performed from room temperature down to T=10 K allowing for the local investigation of e.g. phase transitions in complex oxides.
This thesis includes working with different scanning probe techniques at cryogenic temperatures, examination of various material system as well as analysis of the results.
This work is particularly suitable to be followed by a PhD thesis.
[Tags: Nanooptics, nanotechnology, SNOM, AFM, Laser, IR-Optics, low-temperatures]
Arbeitsgruppe: SNOM
Kontakt: Susanne C. Kehr
geeignet für: MA/PhD
Infrared-spectroscopic examination of 2D-/van-der-Waals materials
In the infrared regime, materials show a characteristic response to electromagnetic radiation due to the excitation of e.g. lattice vibrations, chemical bonds, and charge carrier oscillations. By probing this response via different spectroscopic techniques, materials can be identified as well as regimes of interest, e.g. spectral locations of a materials Reststrahlenband and of intriguing hyperbolic behavior in van der Waals materials. Particularly by comparing the polarization-sensitive response of the complementary techniques of Raman spectroscopy and Fourier-Transform Infrared Spectroscopy (FTIR), these examinations give a full picture of the optical material properties of a sample.
This thesis includes working with optics in the visible and infrared regime, understanding fundamental optical material response, comparing different methods of spectroscopy and fitting them to different models of sample excitation.
This work is particularly suitable to be followed by a PhD thesis.
[Tags: IR, Fourier-Transform Infrared Spectroscopy (FTIR), Raman-Spectroscopy]
Arbeitsgruppe: SNOM
Kontakt: Susanne C. Kehr
geeignet für: MA/PhD