Universität Stuttgart

Permanent URI for this communityhttps://elib.uni-stuttgart.de/handle/11682/1

Browse

Filters

Settings

Institute: search.filters.UBSInstitut.Max-Planck-Institut für FestkörperforschungSubject: search.filters.subject.530

Search Results

Now showing 1 - 10 of 171
  • Thumbnail Image
    ItemOpen Access
    Investigating superconductivity by tunneling spectroscopy using oxide heterostructures
    (2017) Fillis-Tsirakis, Evangelos; Mannhart, Jochen (Prof. Dr.)
  • Thumbnail Image
    ItemOpen Access
    Exploring the growth of refractory metal and sapphire films by thermal laser epitaxy
    (2024) Majer, Lena N.; Mannhart, Jochen (Prof. Dr.)
  • Thumbnail Image
    ItemOpen Access
    From Hermitian to non-Hermitian topological phases of matter
    (2019) Rui, Wenbin; Metzner, Walter (Prof. Dr.)
    The focus of this thesis lies on extending the theory of topological phases of matter from the Hermitian to the non-Hermitian regime. This includes not only the extension of conventional concepts such as topological invariants and topological boundary states in the theory of Hermitian topological phases, but also the exploration and characterization of entirely new topological phases unique to non-Hermitian systems.
  • Thumbnail Image
    ItemOpen Access
    Structure and electronic properties of epitaxial monolayer WSe2
    (2019) Mohammed, Avaise; Takagi, Hidenori (Prof. Dr.)
  • Thumbnail Image
    ItemOpen Access
    Polarized neutron reflectometry study of complex magnetism and hydrogen incorporation in thin-film structures
    (2022) Guasco, Laura; Keimer, Bernhard (Prof. Dr.)
    In this thesis, we present the study of the structural and magnetic properties of simple metals and complex oxide thin films by means of polarized neutron reflectometry. The nuclear and electronic properties of thin films were modified via two routes, namely via hydrogen incorporation, in the case of niobium systems and complex oxide layers, and via depth modulated hole doping, in the case of manganite heterostructures.
  • Thumbnail Image
    ItemOpen Access
    Real-space spectroscopy of interacting quasiparticles in exotic semimetals
    (2022) He, Qingyu; Takagi, Hidenori (Prof. Dr.)
  • Thumbnail Image
    ItemOpen Access
    High quality graphene for magnetic sensing
    (2022) Herlinger, Patrick; Smet, Jurgen (Dr.)
    In this thesis, we investigated the reliable fabrication of high quality graphene and its use as Hall transducer material. Charged impurities and random strain fluctuations were identified as main culprits that deteriorate the electrical properties of graphene devices. It was shown that these extrinsic sources of disorder can be reduced through optimized device processing steps as well as the use of a proper substrate material for graphene such as hexagonal boron nitride (hBN). This insulating material is atomically flat and possesses a very low intrinsic density of charged impurities. By performing Raman spectroscopy and electrical transport measurements, both without and with applied magnetic field, on a large number of different types of graphene devices, it was demonstrated that the encapsulation of graphene between hexagonal boron nitride thin films is the best way to obtain high quality graphene devices. However, even for these hBN-encapsulated devices, we still observed a notable sample-to-sample variation of the electrical properties. Therefore, we developed a post-processing technique that allows us to improve the electrical properties of such devices both significantly and reliably. Since our technique is applied after device fabrication, we could also demonstrate its beneficial effect by comparing one and the same device before and after treatment. We then assessed the application of such high quality graphene as Hall transducer material. The dependencies on and between all relevant operating parameters were explored. This allowed us to develop a deep understanding and empirical model for graphene Hall elements, including the interplay between thermal and 1/f noise in these devices. All key performance indicators for Hall sensors were measured and their typical values reported. For comparable device dimensions, hBN-encapsulated graphene Hall elements were found to have the potential to become a strong competitor to existing materials that are used in today's commercial Hall sensors. Unfortunately, the large-scale fabrication of hBN thin films still remains an unresolved challenge for the industrialization of large area, high quality graphene Hall elements. Also, the Si CMOS integration demands further development. Even though the application of graphene in Hall devices is promising, as shown in this work, this use case alone does likely not justify the significant efforts and investments we expect to be necessary to industrialize the fabrication of high quality graphene devices. Instead, these efforts and costs must be shared by developing a common technology platform for 2D materials that can address several commercially attractive applications where graphene or another 2D material offers superior performance as well. We hope that the insights provided in this work can help to accelerate this process.
  • Thumbnail Image
    ItemOpen Access
    Ultrafast spectroscopy of single quantum dots
    (2012) Wolpert, Christian; Lippitz, Markus (Juniorprofessor Dr.)
    In this thesis, the coherent interaction of single semiconductor quantum dots and ultrafast optical pulses is studied. Under certain conditions, localized exciton transitions in quantum dots can be seen as semi-isolated two-level systems. While this description is sufficient for the explanation of some observations in coherent experiments, it is sometimes necessary to explicitly consider coupling of the discreet quantum states confined to the dot with the environment. We start out from simple, classical examples of coherent spectroscopy and then turn towards experiments where the interaction with the vicinity of the dot becomes an important factor. First, a novel method for transient differential reflectivity spectroscopy of single quantum systems is introduced. It is a pure far-field optical technique which does not require any sophisticated sample preparation steps which makes it applicable to a broad range of structures. Pump pulses excite the sample structure and probe pulses read out the pump-induced changes in the system after a variable delay time. In the case of a single dipole, the signal is given in the form of the spectral inteferogram between the backscattered wave from the particle and the probe light which is reflected at the sample surface. This form of homodyne detection amplifies the weak scattered wave from the particle and thus makes this kind of spectroscopy for single quantum dots feasible. In the remainder of this thesis our spectroscopic method is applied to either characterize the coherent properties of single quantum dots, to prepare and read-out a desired quantum state or to deliberately manipulate them. Coherence times and oscillator strengths are determined for localized exciton transitions. Arbitrary population states can be written by driving coherent population oscillations using resonant pulses, while entangled superpositions of two exciton states in a single dot are investigated by quantum beats on transient differential spectra. We finally exploit the interaction between the dot and a nearby absorbing layer to switch the dot's absorption spectrum on ultrafast timescales via light-induced transient electric fields.
  • Thumbnail Image
    ItemOpen Access
    Organic solar cells : correlation between molecular structure, morphology and device performance
    (2010) Bruder, Ingmar; Weis, Jürgen (Prof. Dr.)
    The development of efficient organic solar cells could be one approach to provide mankind with cheap, sustainable and ecofriendly energy. The introduction of bulk heterojunction and tandem device architectures led recently to devices with power conversion efficiencies close or even higher than n = 6%, showing the potential of organic photovoltaics. Nevertheless, to compete for the foreseeable future to inorganic solar cell technologies, the power conversion efficiencies of organic solar cells have to rise further in the range of 10 % into 15 %. Since the functioning of organic photovoltaics is based on a complex interplay of the electronic properties of its molecular components, it is desirable for an efficient evolution, to identify structural and energetical key characteristics of the molecular components that can lead to efficiency gains. Furthermore, there are virtually no limits for the synthesis of new photoactive materials for the use in organic photovoltaics. Therefore, it is crucial for the device fabrication as well as under a chemical point of view, to narrow potentially promissing classes of molecules and their derivatives under certain physical criteria. One aim of this study was to find and identify so far unknown design criteria for molecules providing high efficiencies in organic solar cells. Thus, the question was raised: What is the physical cause for the differing performance of various metal-phthalocyanines (MPc's with M = Zn, Cu, Ni, Fe) in organic solar cells. Therefore, MPc/C60 based bilayer heterojunction solar cells were fabricated showing a clear dependence of the optimal layer thickness and overall performance on the employed MPc material. Initially, the origin of these differences were explored through structural analysises by AFM and high resolution XRPD measurements on powder and evaporated thin films. The optical properties of the metal phthalocyanines were investigated by solidstate fluorescence and absorption measurements. The lowest excited states of the MPc series were explored by correlated multi-reference ab inito calculations. A high open circuit voltage Voc of a solar cell is a prerequisite for high efficiencies. Unfortunately, the Voc of small molecule based organic solar cells is usually considerably lower than the HOMO-LUMO offset of the device, which determines the theoretical maximum of the Voc in a first approximation. Thus, the question was investigated: What causes the difference between the possible open-circuit voltage and the actual measured voltage and how can this difference be reduced? To answer this question, heterojunction solar cells were produced containing ZnPc or one of the novel synthesized Phenyl-ZnPc, Naphtyl-ZnPc or Anthracenyl-ZnPc as p-conducting and C60 as n-conducting organic layers. By adding the respective aryl substituents to the ZnPc core, the polarizability of the molecules was successively increased. Concurrently, an increase of the Voc from 550 mV to 790 mV by using the highly polarizable Anthracenyl-ZnPc instead of ZnPc was achieved. Quantum mechanical calculations, simulating the charge separation mechanism at the DA-interface of Phenyl-ZnPc/C60 and Naphtyl-ZnPc/C60 showed, that the interplay between characteristic packing and polarization effects could lead to considerably different Coulomb interactions of the electron-hole pairs at the DA-interface. The control of the conduction type and Fermi-level of semiconductors is crucial for the realization of all optoelectronic devices. In inorganic as well as in organic devices this can be achieved by defined doping of appropriate areas within the device. Thus, it has been investigated, how the molecular structure of a dopant should be in order to reduce its diffusivity and increase the evaporation temperature to allow a more efficient processing of the compound. As a result, the novel p-dopant 2,3-di(N-phthalimido)-5,6-dicyano-1,4-benzoquinone (BAPD) was synthesized and compared to the state-of-the-art dopant F4TCNQ. In addition to basic and applied physical questions, I worked on the development of new, efficient solar cell architectures during my PhD thesis. In the course of this work it could be shown, that an efficient organic tandem cell can be prepared from a solid state dye-sensitized solar cell combined with a vacuum-deposited bulk heterojunction solar cell. The complementary absorption of the dyes, as well as an adequate serial connection of both subcells, leads to a high power conversion efficiency of n = (6.0±0.1)% under simulated 100 mW/cm2 AM 1.5 illumination.
  • Thumbnail Image
    ItemOpen Access
    Spectroscopic study of CaMnO3/CaRuO3 superlattices and YTiO3 single crystals
    (2009) Yordanov, Petar; Keimer, Bernhard (Prof. Dr.)
    The first two sections of Chapter 1 give a general overview of the research topics and experimental methods discussed in the thesis. Further on, in Chapter 2, some of the most important characteristics and mechanisms underlying the physics of transition metal oxides are presented. As the experimental part of the thesis includes studies on manganites and titanates, these two classes of compounds are exemplified in the exposition of Chapter 2. Several recent works in the emerging research field of transition metal oxide interfaces and superlattices are also discussed along with a brief introduction in x-ray spectroscopic methods with synchrotron radiation. Chapter 3 introduces the principles of optical spectroscopy and the simplest models for dielectric function, i.e., Lorentz oscillator and Drude dielectric function. The following Chapter 4 introduces two of the experimental techniques in optical spectroscopy, reflectance and spectroscopic ellipsometry. Further on, we describe the design of a new home-built apparatus for near-normal reflectance with high magnetic fields. Several critical technical details and findings during the assembling process are also discussed. Chapter 5 represents a comprehensive experimental spectroscopic study of a prototypical superlattice system made from an antiferromagnetic insulator CaMnO3 and a paramagnetic metal CaRuO3. The resulting interface ferromagnetic state was closely investigated by means of optical spectroscopy as well as by soft x-ray scattering and absorption methods. This study led us to the conclusion that magnetic bound states, i.e. magnetic polarons, have to be considered in the description of this SL system. Chapter 6 describes a polarized far infrared reflectance study with high magnetic field on the ferromagnetic Mott insulator YTiO3, single crystals. All 25 infrared-active phonon modes were observed. The temperature and magnetic-field dependence of the phonon modes revealed a weak spin-phonon coupling in YTiO3 and largely extended temperature range (up to TM ~ 80 - 100K), for the field-induced effects on the oscillator parameters. This later observation, uncovered short-range magnetic order state which remains even at temperatures as high as three times the temperature of the actual ferromagnetic transition of Tc ~ 30K. While a quantitative theoretical description of these data is thus far not available, they point to a complex interplay between spin, orbital, and lattice degrees of freedom due to the near-degeneracy of the Ti t2g orbitals in YTiO3.