Research Phase and Master's Thesis in the Physics programs

An essential step for implementation of quantum computing architectures is an efficient readout of qubits. In the field of superconducting quantum circuits, this is typically realized by dispersively coupling a superconducting qubit to a microwave resonator. Then, the frequency of the resonator depends on the state of the qubit. The former can be extracted by probing the resonator with a coherent  tone. However, efficiency of this readout approach is fundamentally limited by quantum  laws. The corresponding threshold is commonly known as the standard quantum limit and bounds quantum efficiency of the readout process by 50%. Nevertheless, recent investigations have shown that it is possible to circumvent this limit and reach quantum efficiency of the qubit readout of 100% by exploiting broadband readout signal combined with Josephson parametric amplifiers.

The goal of this Master project is to build a proof-of-principle experimental setup and perform microwave cryogenic measurements on a superconducting transmon qubit in the broadband regime in order to demonstrate violation of the standard quantum limit in the dispersive readout.

Modern quantum circuits allow to study strong light-matter interaction in a variety of systems. This so-called strong-coupling regime is key for many aspects of quantum information processing. This project focusses on strong coupling between a paramagnetic electron spin ensemble and a superconducting microwave resonator. Strong coupling is an established phenomenon in this system. However, many aspects regarding the dynamics of this coupled system as well as the non-linear response properties are not fully understood, yet, and we will address these aspects within this project. For this project, we will use superconducting microwave resonators based on NbTiN and spin paramagnetic spin ensembles of phosphorous donors and erbium centers in silicon.

We are looking for a highly motivated master student joining this project. Within your thesis, you will address questions regarding the dynamic response of a strongly coupled system based on a paramagnetic spin ensemble and a microwave resonator. In this context, you will fabricate and optimize microwave resonators and operate them at cryogenic temperatures. In addition, you will use complex microwave pulses, to control the coupled system and experimentally investigate its dynamical response. Within the project, you will learn how to fabricate superconducting microwave resonators in our in-house cleanroom and how to synthesize microwave pulses using arbitrary waveform generators

In this work, you will manufacture your own printed perovskite solar cells and build a new setup for current-voltage measurements of the illuminated solar cells to determine their efficiency.

Next-generation perovskite solar cells show very high efficiencies competitive to silicon solar cells and have the potential to revolutionize photovoltaics in the near future. Their heart is a thin-film absorber that can be easily deposited onto glass or flexible substrate using a slot-die printer.  You will build solar cells with printed perovskite absorber layers, that are compatible with commercialization. Our group has long-standing experience in perovskite fabrication and printing deposition that you can rely on during your work in our group. For characterization, we have the possibility to conduct X-ray scattering for structural analysis and SEM measurements for real-space imaging, among others.

However, the key method of characterizing solar cells is to measure the diode-like current-voltage-behavior of the cell under well-known laboratory illumination. From this measurement, the most important performance parameters such as the efficiency, current characteristics, and internal resistances of your cells can be extracted. In our labs, we already have such a device, but it does not allow measuring our solar cells in inert atmosphere. In this work, you will build a new setup that enables these measurements inside an inert gas atmosphere. The basic concept is already set up, I would be happy if you wish to learn more about this. Further tasks will include strategic planning of the individual components, drawing parts in CAD, guiding our workshop in constructing the parts, and the final assembly of the setup. You will test the setup by characterizing your printed perovskite cells and correlate the findings to your chosen experimental parameters.

Quantum experiments often require fast and versatile data processing which allows for a quantum feedback operation. This approach opens the road to many fascinating experiments such as quantum teleportation, entanglement purification,  quantum error correction, among others. Here, we would like to develop a specific measurement and feedback setup, based on a field programmable gate array (FPGA), for experiments with propagating quantum microwaves.

The main goal is to program and experimentally test a specific image for an FPGA  which would allow for acquisition of microwave signals and feedback generation over few hundred of nanoseconds. This timescale is the prerequisite for exploiting quantum correlations effects for quantum communication and cryptography protocols with propagating squeezed microwaves which are conducted in our lab. This project will offer a deep insight into the state‑of‑the‑art FPGA devices, microwave measurements, and cryogenic experiments with superconductors.

The aim of this Master thesis is to explore different modes of cell wall growth, which is locally controlled by enzymes but has a global effect on the shape of the cell. Which schemes of enzymatic action permit stably growing cell shapes? And which ones can mimick the observed growth behavior of different bacterial species? These fundamental questions are surpisingly largely open, partially due to the difficulty of experimentally determining which local properties of the cell wall affect the enzymatic activity. In light of this experimental barrier, conceptual theoretical models can classify different plausible schemes by their large-scale behavior, which is more easily observed experimentally. This thesis will combine simulations of stochastic models for growing shapes with simple analytical toy models to address some of the open questions.

A member of the k-(ET)₂X family to be studied in this Master thesis exhibits a novel state of matter, quantum spin liquid at ambient pressure. Under a moderate pressure of about 3 kbar the material becomes metallic and superconducting. The aim of the work is to trace the evolution of the conducting system, particularly, of correlation effects, in close proximity to the superconductor-insulator phase boundary. The intrinsic properties of charge carriers will be probed by high-field magnetoresistance effects with the focus on magnetic quantum oscillations. A part of the experiments will be done at the European Magnetic Field Laboratory in steady fields up to 30 T or in pulsed fields up to 80 T.

Physics: Correlated electron systems; magnetic quantum oscillations; unconventional superconductivity.

Techniques: Strong magnetic fields; high pressures; cryogenic (liquid ⁴He; ³He; dilution fridge) techniques; high-precision magnetoresistance measurements.

Contact person:  Mark Kartsovnik (mark.kartsovnik@wmi.badw.de) 

The Centre for astrochemical Studies (CAS) group at the Max Planck Institute for Extraterrestrial Physics includes experts in observations (millimetre and sub-millimetre single dish and interferometry, radio and infrared telescopes), theory (physical processes and dynamics, gas-grain chemical processes and dust evolution, molecular astrophysics and collisional/rate coefficients), and the laboratory (focusing on spectroscopic studies of molecules of astrophysical interest). The combination of observations, theory and laboratory work is crucial to study the physical/chemical structure of an astrophysical object. 

We offer Master Thesis projects on the analysis of single dish and/or interferometric data on star-forming regions in the mm- and sub-mm spectral region. The aim of the project is to obtain, through the information carried by molecular spectra, insights on the physical and chemical processes governing the earliest stages of star formation. Some background in astrophysics is advantageous.

We also offer Master thesis projects on the spectroscopy of molecules of astrophysical interest. The student will have the opportunity to work with several state-of-the-art experiments such as a sub-millimetre free-unit jet. The thesis project will be mainly focused on the acquisition and analysis of spectra that will help the identification of new molecules in the interstellar medium. There will also be the possibility to participate to the further development of the experiment. Some background in molecular spectroscopy is advantageous.

Contacts:
Prof. Paola Caselli  caselli@mpe.mpg.de
Dr. Silvia Spezzano  spezzano@mpe.mpg.de

One of the main challenges in solar cell and sensor manufacturing industry is to understand crucial influencing factors in solar cell design in order to increase the electricity output. A strict understanding of the internal architecture and nanoscale morphology of the polymer-metal nanocomposite films is required.

In a simplified approach of reduced complexity, we are interested in examining the correlation between the interfaces of a charged polymeric interlayer and a potential (metal) electrode. Polyzwitterions possess permanent charges and dipole moments. As such, polyzwitterionic thin (thicknesses between 50-200 nm) films can act as promising zones for the charge carrier diffusion before they reach the electrode and recombine. Plasma treatment can chemically modify the polymer layer, impacting the polymer film’s structure and perhaps hydrophilicity, leading to potential variations in polymer-metal intermixing as well as on the kinetics of metal nuclei formation and growth.

The aim of this master thesis is to explore for the first time how variable plasma etching conditions onto polysulfobetaine (or similar) thin films can affect the nanoscale morphology of different metals sputtered on top of the polysulfobetaine (or similar) thin film under vacuum conditions. The thesis’ deliverables can strongly reinforce design of novel unexplored organic solar cells. 

The Deschler group at the Walter Schottky Institute of TU Munich invites applications for

Master Projects on Magneto-Optical Effects of Novel 2D Materials 

The group
The Deschler group is an independent research group at the Walter Schottky Institute of TU Munich, established through the DFG Emmy-Noether Program and an ERC Starting Grant. Its research focuses on the ultrafast dynamics of functional materials and their applications for energy applications.

More information can be found on our website at www.wsi.tum.de

Your project
You will investigate the outstanding properties of novel 2D magnetic semiconductors with the design and operation of cutting-edge magneto-optical setups to explore the interaction of magnetism and luminescence in these materials.  Specifically, this could be work on one of the following topics or a mixture of both in agreement with your supervisor

• Design of Novel 2D Magnetic Hybrid Perovskites

Due to their outstanding optoelectronic properties and high defect tolerance, organo-metal halide perovskites form an ideal system for efficient magnetic doping. 

There are a lot of promising semiconducting perovskites showing a strong photoluminescence, which are suitable as a host material for magnetic doping with transition metal ions like Mn²⁺, Fe²⁺, Co²⁺ and Ni²⁺. In this project you will fabricate high-quality crystals and thin films with solution-/vapor-based synthesis and investigate them with structural, magnetic and optical measurements to identify the most promising materials.

• Construction and Operation of Magneto-Optical Setups

Materials that combine magnetic and semiconducting properties are desired for spintronic applications.  Optical properties such as the polarization of the luminescence can be controlled via the spin-alignment in these materials. In this project you will design and build a setup for the investigation of magneto-optical effects like Kerr rotation, Faraday rotation, magnetic circular dichroism and magnetic circularly polarized luminescence.

In your Master’s project in our group, you will have the chance to gain hands-on experience in some of the most exciting fields of condensed matter physics. You will run experiments at cryogenic temperatures, control magnetic fields and laser irradiation and learn state-of-the art ultrafast spectroscopy. Dedicated support from a PhD student or postdoc will be available during your project.  You will be expected to make scientific discoveries and contribute to the dynamic atmosphere of our group.

Your application

Applications should be sent to felix.deschler@wsi.tum.de. Please include your CV, a copy of your BSc thesis and the transcript of grades of your BSc studies.  

Organic thermoelectric (TE) materials are nowadays an increasingly emerging topic of research, as they are useful in TE generators to directly convert a temperature gradient into electrical energy. Therefore they are of immense environmental interest in terms of waste heat recovery and the use of solar thermal energy. Recent research has shown that the performance of organic TE materials, especially PEDOT:PSS is strongly dependent on the relative humidity. In this master thesis a new measurement setup will be designed and built, which allows us to investigate TE properties like Seebeck coefficient and electrical conductivity under controlled relative humidity. This setup would give us a huge advantage to better understand the effect of humidity on organic thermoelectric films and to use this knowledge for improving the performance of TE materials. The project will involve a literature review, the development and construction of the new measurement setup to fit the requirements, and in the end the fabrication of organic TE films in the laboratory to test the novel self-made setup.

In optomechanics, light is used to measure and alter the dynamics of mechanical resonators. It is by far the most sensitive method to observe the tiny vibrations that nanomechanical devices perform: in one second one can determine their position with femtometer precision! Using light to measure the mechanics is not the only aspect of optomechanics. The same light can also be used to change the dynamics of the mechanical device through a process called cavity backaction. The photons exert a force on the resonator, the so-called radiation pressure. In this project we want to explore the ultimate limits to this force. The goal is to measure the force originating from a single photon! For this it is required that the photon interacts with the mechanical resonator as strongly as possible. For this we need to the design and make very low loss optical cavities, such as microring resonators. Also, the mechanical device should have a quality factor as high as possible. You will make both the optical and mechanical components from chips with highly-stressed silicon nitride using state-of-the-art nanofabrication in the cleanroom. Then the devices are placed in a vacuum chamber for their measurement. In our highly-automated setup you can very quickly characterize many of the devices on your chip. Then, with the perfect device parameters you can start to explore the more advanced measurements. Initially we can measure the devices in with pulsed light, but by using single photons we want to explore the ultimate limits to optomechanical forces.

See http://www.groups.ph.tum.de/en/qtech/openings/ for a detailed description of this project.

Für den Betrieb des MADMAX Experimentes wurden Piezo Motoren entwickelt, die bei kryogenen Temperaturen (4 K) funktionieren und einen Hub von bis zu 1 m haben. Die ersten gelieferten Prototypmotoren müssen bei kryogenen Temperaturen getestet und auf verschiedene Betriebsparameter untersucht werden. Qualification of Piezo motors at cryogenic temperatures for the MADMAX axion dark matter experiment In the context of the MADMAX dark matter axion search experiment Piezo motors have been developed for operation at cryogenic temperatures (4 K) for a stroke of up to 1 m. The first prototype motors that have been delivered will need to be tested at cyrogenic temperatures and several parameters need to be investigated.

Quantum optics is an extremely powerful approach towards quantum communication, quantum sensing, and quantum computing. In particular, quantum information stored in photons has very low decoherence and can be transmitted over large distances through optical fibers. To date, most experiments in quantum optics use optical tables full with mirrors and beam splitters that all have to be carefully aligned and stabilized. This may be good enough for initial demonstrations, but in order to bring quantum science into the realm of quantum technology, a more scalable approach is required.

With our expertise in making photonic chips using advanced nanofabrication, we are making putting these exciting quantum optics experiments on chips. Here, light is routed via optical waveguides. Furthermore, by bending a waveguide, one gets the equivalent of a free-space mirror; a beam splitter cube becomes a directional coupler and so on. By combining these elements, we can make the building block for e.g. an optical quantum computer. With that, the possibilities are almost unlimited.

For such large-scale optical quantum circuits we also want to incorporate single-photon sources, superconducting single-photon detectors, and optomechanical phase shifters. This all happens on a single chip. Making and characterizing the components is the first step and from there on, you are making more and more complex quantum chips. You will be doing the nanofabrication in the cleanroom, and then use our optical measurement setups to see how each device is performing. Depending on your preference, it may also be possible to add a modelling component to the project.

See http://www.groups.ph.tum.de/en/qtech/openings/ for a detailed description of this project.

Optomechanics provides extremely sensitive methods to measure the displacement of mechanical resonators. However, the forces are much smaller in optomechanics compared to those in nanoelectromechanical systems (NEMS). The goal of the project is to make, and measure opto-electromechanical devices which have strong electrostatic interactions. This includes the electrostatic spring effect where the resonance frequency depends strongly on the applied voltage. The next step is trying to measure the potential by measuring the ringdown of different mechanical modes. The devices will be made using advanced nanofabrication techniques such as electron beam lithography and reactive ion etching.

See http://www.groups.ph.tum.de/en/qtech/openings/ for a detailed description of this project.

More than half of the stars forms in multiple systems. The dynamical interactions between the multiple stars can have a profound influence on the formation and evolution of stars and planets. This, however, is not well understood, especially at the early stages of star formation, due to the difficulty of observing young stars obscured by its surrounding natal cloud. Recent high-resolution ALMA (the Atacama Large Millimeter/submillimeter Array) observations have spatially resolved the emission from complex organic molecules around a very young protostellar binary system [1], also constraining the stellar masses and orbital parameters. The emission from these molecules coincides with features seen in the dust around the binary accretion disks, possibly corresponding to spirals or tightly wound structures. These features are difficult to explain if the emission arises solely due to heating from the forming protostars, the most common scenario used to explain the appearance of warm complex organic molecule emission around protostars. We propose to investigate the role of shocks created by the binary interactions in the production and distribution of molecular tracers at scales from a few up to 100 astronomical units. Gravitational forces from the binary stars can create shocks in the disk surrounding them. Detailed numerical simulations will be needed to investigate the temperature and density structure created by the interaction. This study will shed light on how the binary interactions can influence the chemical inventory in multiple systems at planet formation scales. During this master project, the student will carry out 3D hydrodynamical simulations with the orbital and gas properties observed in the protostellar binary [2]. Detailed thermo-dynamics will be built to investigate the origin of the high temperature and density tracers seen in the gas phase towards this embedded binary system. The student will analyze the spirals or other types of shocks features formed in the simulations, and how it depends on the numerical and physical parameters.

Prerequisites: Basic knowledge in programming (C/C++ and Python will be used).

Contact: Dr. Munan Gong <munan@mpe.mpg.de>, Dr. Maria Jose Maureira <maureira@mpe.mpg.de>, Prof. Dr. Paola Caselli <caselli@mpe.mpg.de>

[1] Maureira et el. 2020, "Orbital and Mass Constraints of the Young Binary System IRAS 16293-2422 A". The Astrophysical Journal 897.

[2] Moody et al. 2019, "Hydrodynamic Torques in Circumbinary Accretion Disks", The Astrophysical Journal 875.

Synchronization is a universal phenomenon that is knows since they days of Huygens. When two or more oscillators with slightly different frequencies are coupled, they will start to move in phase. We can create small mechanical devices using advanced nanofabrication techniques here on campus. By sending light of the right wavelength, they start to oscillate, and when increasing the power the optomechanical coupling synchronizes them. The goal of this project is to synchronize devices made from silicon nitride, which is a special material with a lot of stress in it, and to increase the number of synchronized oscillators. The larger the system becomes, the richer the nonlinear dynamics will become. You will first make the devices in the cleanroom, measure them, and analyze the data.

See http://www.groups.ph.tum.de/en/qtech/openings/ for a detailed description of this project.

Im Rahmen des MADMAX Projektes zur Suche nach dunkler Materie Axionen werden verschiedene
Testaufbauten bei Raumtemperatur und in flüssigem Helium (4 K)
zur Kalibrierung und zur Untersuchung der genauen Signalantwort des
experimentellen Aufbaus betrieben. Es werden Reflektionsdaten Daten
genommen und ausgewertet.

In the frame work of the MADMAX projects several test stands at room tamperature and in liquid helium
for the investigation of the detailled system response and for calibration of the setup are being operated. Reflectivity data will be atken and analyzed.

Kernreaktionsanalyse (Nuclear Reaction Analysis, NRA) ist eine sehr empfindliche Methode zum quantitativen Nachweis und zur Tiefenprofilierung von leichten Elementen in der Materialanalytik. NRA mit einfallenden 3He Ionen im Energiebereich von einigen MeV ist hierbei besonders vorteilhaft. Zur quantitativen Anwendung benötigt man allerdings die möglichst genaue Kenntnis des differentiellen Wirkungsquerschnittes. Viele Wirkungsquerschnitte sind leider nur fragmentarisch und oft nur mit großen Unsicherheiten bekannt.

Im Rahmen der Masterarbeit sollen zunächst die Proben für die Wirkungsquerschnittsmessungen mittels Abscheidung aus einem Niedertemperaturplasma hergestellt werden und dann die differentiellen Wirkungsquerschnitte für die Reaktionen 9Be(3He,p)11B, 12C(3He,p)14N sowie 13C(3He,p)15N bei verschiedenen Streuwinkeln im Energiebereich 1-5 MeV gemessen werden. Die Messungen werden am 3 MV Tandembeschleuniger des Max-Planck-Instituts für Plasmaphysik durchgeführt.

Contact: Dr. Matej Mayer