The development of stylolites, from small-scale heterogeneities to multi-scale roughness

Stylolites are rough paired surfaces, indicative of localized stress-induced dissolution under a non-hydrostatic state of stress, separated by a clay parting which is believed to be the residuum of the dissolved rock. These structures are the most frequent deformation pattern in monomineralic rocks and thus provide important information about low temperature deformation and mass transfer. The intriguing roughness of stylolites can be used to assess amount of volume loss and paleo-stress directions, and to infer the destabilizing processes during pressure solution. But there is little agreement on how stylolites form and why these localized pressure solution patterns develop their characteristic roughness.rnNatural bedding parallel and vertical stylolites were studied in this work to obtain a quantitative description of the stylolite roughness and understand the governing processes during their formation. Adapting scaling approaches based on fractal principles it is demonstrated that stylolites show two self affine scaling regimes with roughness exponents of 1.1 and 0.5 for small and large length scales separated by a crossover length at the millimeter scale. Analysis of stylolites from various depths proved that this crossover length is a function of the stress field during formation, as analytically predicted. For bedding parallel stylolites the crossover length is a function of the normal stress on the interface, but vertical stylolites show a clear in-plane anisotropy of the crossover length owing to the fact that the in-plane stresses (σ2 and σ3) are dissimilar. Therefore stylolite roughness contains a signature of the stress field during formation.rnTo address the origin of stylolite roughness a combined microstructural (SEM/EBSD) and numerical approach is employed. Microstructural investigations of natural stylolites in limestones reveal that heterogeneities initially present in the host rock (clay particles, quartz grains) are responsible for the formation of the distinctive stylolite roughness. A two-dimensional numerical model, i.e. a discrete linear elastic lattice spring model, is used to investigate the roughness evolving from an initially flat fluid filled interface induced by heterogeneities in the matrix. This model generates rough interfaces with the same scaling properties as natural stylolites. Furthermore two coinciding crossover phenomena in space and in time exist that separate length and timescales for which the roughening is either balanced by surface or elastic energies. The roughness and growth exponents are independent of the size, amount and the dissolution rate of the heterogeneities. This allows to conclude that the location of asperities is determined by a polimict multi-scale quenched noise, while the roughening process is governed by inherent processes i.e. the transition from a surface to an elastic energy dominated regime.rn

Strategisches TV-Management: Erlösdiversifizierung privater deutscher Free-TV-Unternehmen

Die vorliegende Arbeit befasst sich mit der Erlösdiversifizierung privater deutscher Free-TV-Unternehmen. Im Zentrum stehen dabei die Entwicklung eines Nutzwerttheo-rie-basierten Modells zur Bestimmung attraktiver Diversifikationsfelder und dessen empirische Überprüfung. Zur Modellbildung werden sowohl der market-based als auch der resource-based View des strategischen Managements berücksichtigt und methodisch integriert. Zunächst werden anhand von Fallstudien der Mediengruppe RTL Deutsch-land und der ProSiebenSat.1 Media AG der strategische Optionsraum bestehend aus 15 Diversifizierungsmärkten identifiziert und die Kernressourcen deutscher Free-TV-Unternehmen untersucht. Aufbauend auf den gewonnenen Erkenntnissen wird das soge-nannte COAT-Diversifizierungsmodell als Rahmenmodell für die Planung und Bewer-tung von Diversifizierungsstrategien entworfen (COAT = Online Content Distribution, Offline Activities und Add-On Services/ Transaction TV). Durch eine ausführliche Be-fragung von 26 hochrangigen Managern, Senderchefs und Branchenbeobachtern der deutschen TV-Industrie wird das entworfene Modell überprüft und die Attraktivität der identifizierten Diversifizierungsmärkte ermittelt. Im Zentrum des Modells und der Ex-pertenbefragung steht die Durchführung einer Nutzwertanalyse, anhand derer zum einen die Marktattraktivität der verschiedenen Diversifizierungsmärkte ermittelt wird (market-based View), und zum anderen die Bedeutung der Kernressourcen eines Free-TV-Unternehmens in den verschiedenen Diversifizierungsmärkten untersucht wird (ressour-ce-based View). Hierzu werden für beide Dimensionen entsprechende Subkriterien de-finiert und eine Nutzwertbewertung für jedes Kriterium in jedem der 15 Märkte vorge-nommen. Aus den ermittelten Teilnutzwerten können für jeden untersuchten Markt ein übergreifender marktorientierter Nutzwert NM und ein ressourcenorienterter Nutzwert NR ermittelt werden. Im Resultat lässt sich ein Nutzwert-Portfolio aufspannen, in dem die 15 Diversifizierungsmärkte entsprechend ihrer ressourcen- und marktorientierten Nutzwertkombinationen in vier Gruppen kategorisiert werden: Diversifizierungsmärkte mit 1) sehr hoher Attraktivität, 2) hoher Marktchance, 3) hoher Opportunität oder rn4) geringer Attraktivität. Abschließend werden erste Normstrategien für die einzelnen Diversifizierungskategorien abgeleitet und die Eignung des COAT-Diversifizierungs-modells für die strategische Planung analysiert.rn

Preparation and functional characterisation of recombinant silicatein-alpha from the sponge Suberites domuncula

The marine world is an immense source of biodiversity that provides substances with striking potentials in medicinal chemistry and biotechnology. Sponges (Porifera) are marine animals that represent the most impressive example of organisms possessing the ability to metabolise silica through a family of enzymes known as silicateins. Complex skeletal structures (spicules) made of pure biogenic silica (biosilica) are produced under physiological conditions. Biosilica is a natural material comprising inorganic and organic components with unique mechanical, optical, and physico-chemical properties, including promising potential to be used for development of therapeutic agents in regenerative medicine. Unravelling the intimate physiological mechanisms occurring in sponges during the construction of their siliceous spicules is an on-going project, and several questions have been addressed by the studies proposed by our working group. In this doctoral work, the recombinant DNA technology is exploited for functional and structural characterisation of silicatein. Its precursors are produced as fusion proteins with a chaperone tag (named TF-Ps), and a robust method for the overexpression of native soluble proteins in high concentrations has been developed. In addition, it is observed and proven experimentally that the maturation of silicatein is an autocatalytic event that: (i) can be modulated by rational use of protease inhibitors; (ii) is influenced by the temperature of the environment; (iii) only slightly depends on the pH. In the same experimental framework, observations on the dynamics in the maturation of silicateins allow a better understanding of how the axial filaments form during the early stages of spicule construction. In addition, the definition of new distinct properties of silicatein (termed “structure-guiding” and “structure-forming”) is introduced. By homology models and through comparisons with similar proteins (the cathepsins), domains with significant surface hydrophobicity are identified as potential self-assembly mediators. Moreover, a high-throughput screening showed that TF-Ps could generate crystals under certain conditions, becoming promising for further structural studies. With the goal of optimise the properties of the recombinant silicatein, implementation of new production systems are tried for the first time. Success in the expression of silicatein-type proteins in insect and yeast cells, constitute a promising basis for further development, towards the establishment of an efficient method for the production of a high-value pure and soluble protein.