Research Phase and Master's Thesis in the Physics programs

The characterization of lattice defects with respect to their chemical environment is of outmost interest in condensed matter physics and materials science. In coincidence Doppler-broadening spectroscopy (CDBS), both annihilation quanta are detected simultaneously with two high-purity germanium detectors. The resulting background suppression enables the detection of large momenta of core electrons (large Doppler-shifts) in the outer wings of the 511 keV annihilation line. Therefore, CDBS is applied to identify the elements at the annihilation site and hence enables the detection of, e.g., foreign atom-vacancy complexes or precipitates in alloys. Within this thesis CDBS spectra resulting from positron annihilation in point defects will be calculated by using the open-source code ABINIT. This program is based on density functional theory (DFT) and allows the computation of electron and positron densities as well as wave functions in the solid. The calculated  positron lifetimes and positron-electron momentum distributions are compared with experimental results.

The project is carried out within the TUM research group Physics with Positrons.

Electrocatalysis technologies, including PEM fuel cells, can help to shape a sustainable energy future in which PEM fuel cells provide versatile stationary and portable power solutions. However, one key factor limiting their widespread commercialization are high costs for large platinum (Pt) loadings, which are required to catalyze the sluggish oxygen reduction reaction (ORR) at the fuel cell cathode. Thus, enhancing the catalyst activity with respect to the Pt mass is of great interest.

In this MSc work, we capitalize on data-driven design to propose new Pt catalysts with enhanced mass activities toward the ORR. We link experimental data with results from density functional theory (DFT) on Pt-based ORR catalysts to build a computational model which predicts mass activities.

The thesis will focus on generalizing a developed method based on generalized coordination numbers for high-throughput screenings to tailor electrocatalyst shapes and sizes toward optimized mass activities. In particular, we want to explore core-shell nanoparticles. In core-shell nanoparticles, the catalysis is driven on active Pt shells, but cheaper and more abundant metals at the core limit the precious Pt loading. 

Contact: Prof. Alessio Gagliardi alessio.gagliardi@tum.de or Prof. Aliaksandr Bandarenka bandarenka@ph.tum.de 

References

[1] M. Rueck, A. Bandarenka, F. Calle-Vallejo, A. Gagliardi, “Oxygen Reduction Reaction: Rapid Prediction of Mass Activity of Unstrained Nanostructured Platinum Electrocatalysts,” J. Phys. Chem. Lett., 2018, 9 (15), 4463-4468. DOI:10.1021/acs.jpclett.8b01864.

[2] B. Garlyyev(1), K. Kratzl(1), M. R¨uck(1), J. Michalicka, J. Fichtner, J. Macak, T. Kratky, S. Guenther, M. Cokoja, A.S. Bandarenka, A. Gagliardi, R.A. Fischer, “Optimizing the Size of Platinum Nanoparticles for Enhanced Oxygen Electro-Reduction Mass Activity,” Angew. Chem. Int. Ed., 2019, 58 (28), 9596-9600. DOI:10.1002/anie.201904492

[3] M. Rueck, A. Bandarenka, F. Calle-Vallejo, A. Gagliardi, “Fast Identification of Optimal Pure Platinum Nanoparticle Shapes and Sizes for Efficient Oxygen Electroreduction,” Nanoscale Adv., 2019, 1 (8), 2901–2909. DOI:10.1039/c9na00252a

[4] M. Rueck, B. Garlyyev, F. Mayr, A.S. Bandarenka, A. Gagliardi, “Oxygen Reduction Activities of Strained Platinum Core–Shell Electrocatalysts Predicted by Machine Learning,” J. Phys. Chem. Lett., 2020, 11 (5), 1773-1780. DOI:10.1021/acs.jpclett.0c00214

Dark-field radiography exploits the scattering of X-rays to reveal structures in lung tissue that cannot be visualized with conventional imaging. Currently, several initial clinical patient studies are underway on a worldwide first prototype we recently realized at Klinikum rechts der Isar. Within the scope of this project, special registration algorithms are to be developed that can register thorax images in inhalation and exhalation and allow local differences between ventilation states (for example in certain lung diseases).

Character of thesis work: mainly computational physics & image processing

For more information, please contact: Rafael Schick (rafael.schick@tum.de) or Franz Pfeiffer (franz.pfeiffer@tum.de).

Dark-field computed tomography uses the wave property of X-rays to provide complementary contrasts in X-ray imaging. In this project, an existing prototype for dark-field CT in mice will be used to explore the use of dark-field contrast in pre-clinical research for improved detection of lung diseases in collaboration with the Helmholtz Center for Health. In addition to experimental work to support the conduct of the preclinical studies, algorithmic research to reduce image noise and dose is planned.

Character of thesis work: experimental medical physics (60%) & image processing (40%).

For more information, please contact: Benedikt Guenther (benedikt.guenther@mytum.de), Simon Zandarco (simon.zandarco@tum.de) or Franz Pfeiffer (franz.pfeiffer@tum.de).

Implementation of region-of-interest mode
in diffraction computed tomography

Since its development, X-ray tomography became a non-alternative tool for fast and non-destructive characterisation of different objects providing an in-depth resolved information from the interior of materials, devices and living organisms. Besides the overall popularity and the widley use of the method it suffers heavily from contrast limitation issues, which are directly related to the underlying properties of X-ray attenuation. One of the approaches to enhance the sensitivity of the method (at least in the field of solid-state applications) is the utilization of a diffraction-based input signal instead/together with the absorption-based signal information. X-ray diffraction radiography – a scanning technique taking XRD pattern at each scanning position\pixel (and tomography, as its logical continuation) is a relatively new method for sample characterisation, which requires requiring a large amount of diffraction data as input. However, it is capable to provide unique information about the organisation and composition of the studied objects. The size of diffraction data in a XRD-CT dataset is one of the limiting factors for the resolution of the measurement, i.e. for larger samples. A possible solution for this would be a limitation to certain region-of-interest within the objects volume. Thus, the aim of the proposed thesis is the validation of available approaches for reconstruction of XRD-CT data in the region-of-interest mode and its application for non-destructive studies of cylindrical Li-ion batteries.

Common supervision is foreseen with Dr. Anatoliy Senyshyn, diffraction group leader at MLZ.

Our group is actively developing optical atomic magnetometers, a type of sensors using light-atom interactions to detect magnetic fields.This approach, sitting on the junction of laser-optics, quantum-optics and atom-physics, offer a wide range of possibilities for undergraduate and graduate students, from theoretical approaches to practical experiments.

Possible thesis projects are: the Characterization of a non-magnetic Optical Atomic Magnetometer Array at the panEDM Experiment (at ILL), the Development of a non-magnetic Free Space Cesium Magnetometer, the Development of an Optical Earth Field Cesium Magnetometer, the Characterisation and Improvement of Cesium Vapor Cells and Upgrading and Characterisation of a Magnetically Shielded Test Chamber for Magnetometers.

Students can learn a variety of skills, such as handling laser optics and different measurement systems, designing sensors, or developing operating and analysis software.

If you are interested or want to learn more on this topic - feel free to contact philipp.roessner@tum.de!

Providing higher order QCD corrections to the hadronic production of top quarks at the LHC is an important step towards obtaining a more detailed understanding of electroweak symmetry breaking, due to the fact that top quarks receive their mass through interactions with the Higgs background field. Single top production is one of the most prominent top quark production channels at the LHC, with the t-channel process, which involves the production of a single top quark mediated by an exchange of a W boson, accounting for 70% of all single top quarks produced at LHC collisions. Recently, NNLO corrections to the so-called non-factorisable contributions to the single top t-channel were computed. The calculation was performed by calculating all the relevant 2-loop Feynman integrals numerically. It will be the aim of this project to provide an efficient analytic representation of these integrals in terms of special functions (e.g. multiple polylogarithms), by employing modern methods of multiloop calculations such as integration-by-part identities, canonical differential equations and the study of the relevant special functions.