@phdthesis{Hoepfner2012,
  author    = {H{\"o}pfner, Philipp Alexander},
  title     = {Two-Dimensional Electron Systems at Surfaces — Spin-Orbit Interaction and Electronic Correlations},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-78876},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2012},
  abstract  = {This thesis addresses three different realizations of a truly two-dimensional electron system (2DES), established at the surface of elemental semiconductors, i.e., Pt/Si(111), Au/Ge(111), and Sn/Si(111). Characteristic features of atomic structures at surfaces have been studied using scanning tunneling microscopy and low energy electron diffraction with special emphasis on Pt deposition onto Si(111). Topographic inspection reveals that Pt atoms agglomerate as trimers, which represent the structural building block of phase-slip domains. Surprisingly, each trimer is rotated by 30° with respect to the substrate, which results in an unexpected symmetry breaking. In turn, this represents a unique example of a chiral structure at a semiconductor surface, and marks Pt/Si(111) as a promising candidate for catalytic processes at the atomic scale. Spin-orbit interactions (SOIs) play a significant role at surfaces involving heavy adatoms. As a result, a lift of the spin degeneracy in the electronic states, termed as Rashba effect, may be observed. A candidate system to exhibit such physics is Au/Ge(111). Its large hexagonal Fermi sheet is suggested to be spin-split by calculations within the density functional theory. Experimental clarification is obtained by exploiting the unique capabilities of three-dimensional spin detection in spin- and angle-resolved photoelectron spectroscopy. Besides verification of the spin splitting, the in-plane components of the spin are shown to possess helical character, while also a prominent rotation out of this plane is observed along straight sections of the Fermi surface. Surprisingly and for the first time in a 2DES, additional in-plane rotations of the spin are revealed close to high symmetry directions. This complex spin pattern must originate from crystalline anisotropies, and it is best described by augmenting the original Rashba model with higher order Dresselhaus-like SOI terms. The alternative use of group-IV adatoms at a significantly reduced coverage drastically changes the basic properties of a 2DES. Electron localization is strongly enhanced, and the ground state characteristics will be dominated by correlation effects then. Sn/Si(111) is scrutinized with this regard. It serves as an ideal realization of a triangular lattice, that inherently suffers from spin frustration. Consequently, long-range magnetic order is prohibited, and the ground state is assumed to be either a spiral antiferromagnetic (AFM) insulator or a spin liquid. Here, the single-particle spectral function is utilized as a fundamental quantity to address the complex interplay of geometric frustration and electronic correlations. In particular, this is achieved by combining the complementary strengths of ab initio local density approximation (LDA) calculations, state-of-the-art angle-resolved photoelectron spectroscopy, and the sophisticated many-body LDA+DCA. In this way, the evolution of a shadow band and a band backfolding incompatible with a spiral AFM order are unveiled. Moreover, beyond nearest-neighbor hopping processes are crucial here, and the spectral features must be attributed to a collinear AFM ground state, contrary to common expectation for a frustrated spin lattice.},
  subject      = {Halbleiteroberfl{\"a}che},
  language  = {en}
}
@phdthesis{Scheiderer2019,
  author    = {Scheiderer, Philipp},
  title     = {Spectroscopy of Prototypical Thin Film Mott Materials},
  doi       = {10.25972/OPUS-18635},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-186358},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2019},
  abstract  = {The rich phase diagram of transition metal oxides essentially roots in the many body physics arising from strong Coulomb interactions within the underlying electron system. Understanding such electronic correlation effects remains challenging for modern solid state physics, therefore experimental data is required for further progress in the field. For this reason, spectroscopic investigations of prototypical correlated materials are the scope of this thesis. The experimental methods focus on photoelectron spectroscopy, and the test materials are the correlated metal SrVO\(_3\) and the Mott insulator LaTiO\(_3\), both of which are fabricated as high quality thin films. In SrVO\(_3\) thin films, a reduction of the film thickness induces a dimensional crossover from the metallic into the Mott insulating phase. In this thesis, an extrinsic chemical contribution from a surface over-oxidation is revealed that emerges additionally to the intrinsic change of the effective bandwidth usually identified to drive the transition. The two contributions are successfully disentangled by applying a capping layer that prevents the oxidation, allowing for a clean view on the dimensional crossover in fully stoichiometric samples. Indeed, these stoichiometric layers exhibit a higher critical thickness for the onset of the metallic phase than the bare and therefore over-oxidized thin films. For LaTiO\(_3\) thin films, the tendency to over-oxidize is even stronger. An uncontrolled oxygen diffusion from the substrate into the film is found to corrupt the electronic properties of LaTiO\(_3\) layers grown on SrTiO\(_3\). The Mott insulating phase is only detected in stoichiometric films fabricated on more suitable DyScO\(_3\) substrates. In turn, it is demonstrated that a \(controlled\) incorporation of excess oxygen ions by increasing the oxygen growth pressure is an effective way of \(p\) doping the material which is used to drive the band filling induced Mott transition. Gaining control of the oxygen stoichiometry in both materials allows for a systematic investigation of correlation effects in general and of the Mott transition in particular. The investigations are realized by various photoelectron spectroscopy techniques that provide a deep insight into the electronic structure. Resonant photoemission not only gives access to the titanium and vanadium related partial density of states of the valence band features, but also shows how the corresponding signal is enhanced by tuning the photon energy to the \(L\) absorption threshold. The enhanced intensity turns out to be very helpful for probing the Fermi surface topology and band dispersions by means of angular-resolved photoemission. The resulting momentum resolved electronic structure verifies central points of the theoretical description of the Mott transition, viz. the renormalization of the band width and a constant Luttinger volume in a correlated metal as the Mott phase is approached.},
  subject      = {{\"U}bergangsmetalloxide},
  language  = {en}
}