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    Magnetic Moment Tensor Potentials for collinear spin-polarized materials reproduce different magnetic states of bcc Fe
    (2022) Novikov, Ivan; Grabowski, Blazej; Körmann, Fritz; Shapeev, Alexander
    We present the magnetic Moment Tensor Potentials (mMTPs), a class of machine-learning interatomic potentials, accurately reproducing both vibrational and magnetic degrees of freedom as provided, e.g., from first-principles calculations. The accuracy is achieved by a two-step minimization scheme that coarse-grains the atomic and the spin space. The performance of the mMTPs is demonstrated for the prototype magnetic system bcc iron, with applications to phonon calculations for different magnetic states, and molecular-dynamics simulations with fluctuating magnetic moments.
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    Genetisch modifizierte Biotemplate zur Erzeugung von Zr-basierten Nanomaterialien
    (2019) Eisele, Rahel; Bill, Joachim (Prof. Dr.)
    In Biomineralisationsprozessen aus der belebten Natur scheiden sich anorganische Materialien auf organischen Templaten (Biomakromoleküle) ab. Funktionelle Gruppen der Makromoleküle steuern dabei die Abscheidung aus einer wässrigen Lösung sowie die Strukturierung des anorganischen Materials. Dabei sind spezifische Wechselwirkungen zwischen dem organischen Templat und dem anorganischen Material von Bedeutung. Die Materialbildung findet unter Umgebungsbedingungen in wässrigen Systemen statt. Für technisch interessante Materialien wie Zirkoniumdioxid (ZrO2) stellt die energieeffiziente Herstellung präziser Nanostrukturen eine technische Herausforderung dar. Daher wurden im Rahmen dieser Arbeit die Prinzipien der Biomineralisation auf die Herstellung von Zirkonium-basiertem Material (ZrbM) übertragen. Hierzu gehörte die Materialbildung durch Mineralisation aus einer ZrOCl2-Lösung sowie eine gezielte Mineralisation auf bioorganischen M13-Bakteriophagentemplaten. Um die „biologische Spezifität“ in Biomineralisationsprozessen auf die Bildung von ZrbM zu übertragen, wurden Peptide mittels Phagen-Display identifiziert, die spezifisch an ZrO2 binden. Mittels genetischer Modifikation wurden diese ZrO2 Bindepeptide auf der Phagenoberfläche präsentiert. Hierdurch wurde eine hohe Bindepeptiddichte und damit viele Interaktionspunkte zum anorganischen Material erzielt. Bevor der Einfluss dieser Bindepeptide auf die Mineralisation von ZrbM untersucht werden konnte, wurde zunächst der Partikelbildungs- und Partikelwachstumsprozess von ZrbM in einer ZrOCl2-Lösung und einem Ethanol-Wasser Lösungsmittelgemisch bei verschiedenen System- und Prozessparametern beschrieben. Auf Grundlage dieser Ergebnisse wurde eine Mineralisationslösung etabliert mit der der Einfluss der Bindepeptide - präsentiert auf der Phagenoberfläche - auf die Mineralisation von ZrbM untersucht werden konnte. Die Bindepeptide zeigten einen deutlichen Einfluss auf die Mineralisation von ZrbM. Im Vergleich zu Bakteriophagen ohne Bindepeptid wurde mit den genetisch modifizierten Bakteriophagen eine deutlich höhere Abscheiderate erzielt. Dieser Einfluss der Bindepeptide wurde auf Hydroxygruppen in Serineinheiten zurückgeführt. Diese führen zum einen zu einer starken Anziehung von molekularen Zr-Spezies an das Biotemplat. Zum anderen induzieren die Hydroxygruppen die heterogene Keimbildung von ZrbM durch Kondensationsreaktionen zwischen dem Biotemplat und molekularen Zr-Spezies. Somit ist es nun möglich genetisch kontrolliert Zr-basierte Nanomaterialien zu mineralisieren. Im Rahmen dieser Arbeit gelang es nicht nur einzelne Phagen zu mineralisieren, sondern auch dünne homogene Schichten aus ZrbM. Diese ZrbM-Schichten wurden im letzten Teil dieser Arbeit vergleichend zu Phagenschichten und SiO2-Schichten auf die Adhäsion von Staphylococcus aureus (S. aureus) getestet. S. aureus ist ein pathogenes Bakterium, welches zur Bildung von Biofilmen, zum Beispiel auf Implantaten, und dadurch zu einem Implantatverlust bis hin zu lebensbedrohlichen Komplikationen führen kann. Die Biofilmbildung kann effektiv unterbunden werden, indem die Bakterienadhäsion auf Oberflächen verhindert wird. Daher wurde im Rahmen dieser Arbeit untersucht, ob bestimmte chemische Oberflächen, das heißt bestimmte Materialien oder auch bestimmte funktionelle Gruppen, die Bakterienadhäsion unterdrücken können. Die Untersuchung der Bakterienadhäsion auf den verschiedenen Oberflächen ergab, dass auf der Phagenschicht im Vergleich zur SiO2-Schicht und einer Schicht aus ZrbM eine sehr geringe Bakterienadhäsion vorlag. Untersuchungen verschiedener Einflussfaktoren auf die Bakterienadhäsion zeigten, dass die Bakterienadhäsion an der SiO2-Schicht und der ZrbM-Schicht durch die Oberflächenrauigkeit, die Hydrophobizität und die Oberflächenladung beeinflusst werden kann. Bei der Phagenschicht korrelierten weder die Oberflächenladung, noch die Oberflächenrauigkeit und die Hydrophobizität im Vergleich zu den anorganischen Materialoberflächen mit der Bakterienadhäsion. Dies ließ darauf schließen, dass die geringe Bakterienadhäsion auf der Phagenschicht auf die biochemische Zusammensetzung der Hüllproteine, vor allem auf die Abwesenheit spezifischer Bindedomänen (Ligand-Rezeptor-Wechselwirkungen), zurückzuführen ist.
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    Peptide controlled shaping of biomineralized tin(II) oxide into flower-like particles
    (2019) Kilper, Stefan; Jahnke, Timotheus; Wiegers, Katharina; Grohe, Vera; Burghard, Zaklina; Bill, Joachim; Rothenstein, Dirk
    The size and morphology of metal oxide particles have a large impact on the physicochemical properties of these materials, e.g., the aspect ratio of particles affects their catalytic activity. Bioinspired synthesis routes give the opportunity to control precisely the structure and aspect ratio of the metal oxide particles by bioorganic molecules, such as peptides. This study focusses on the identification of tin(II) oxide (tin monoxide, SnO) binding peptides, and their effect on the synthesis of crystalline SnO microstructures. The phage display technique was used to identify the 7-mer peptide SnBP01 (LPPWKLK), which shows a high binding affinity towards crystalline SnO. It was found that the derivatives of the SnBP01 peptide, varying in peptide length and thus in their interaction, significantly affect the aspect ratio and the size dimension of mineralized SnO particles, resulting in flower-like morphology. Furthermore, the important role of the N-terminal leucine residue in the peptide for the strong organic-inorganic interaction was revealed by FTIR investigations. This bioinspired approach shows a facile procedure for the detailed investigation of peptide-to-metal oxide interactions, as well as an easy method for the controlled synthesis of tin(II) oxide particles with different morphologies.
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    Interaction of carbon and nitrogen in iron
    (Stuttgart : Max-Planck-Institut für Intelligente Systeme (ehemals Max-Planck-Institut für Metallforschung), 2016) Göhring, Holger; Mittemeijer, Eric Jan (Prof. Dr. Ir.)
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    Grain growth and texture evolution in copper thin films
    (2010) Sonnweber-Ribic, Petra; Arzt, Eduard (Prof. Dr. phil)
    An improved basic understanding of mechanisms causing grain growth and texture evolution in Cu thin films contains the potential to improve performance and reliability of components and devices. In this work, the influence of film thickness, strain and temperature on grain growth and texture evolution in Cu thin films was investigated. By varying the parameters, information about the underlying mechanisms were revealed. The 0.5 to 10 micrometer thick Cu films were deposited on 125 micrometer thick polyimide substrates (Kapton®, DuPont) using a UHV magnetron sputtering system. For detailed observation of grain growth and texture evolution an EBSD-based in situ testing appliance was constructed. This system allowed the simultaneous observation of grain growth and texture evolution, giving new insight into growth kinetics and details of grain growth. In a first step, Cu thin films of thicknesses in between 0.5 and 10 micrometer were deposited on polymer substrates and annealed at 330°C for 30 min. Their resulting texture and microstructure were investigated by EBSD. A texture transition from (111) to (100) was observed at film thicknesses between 3 and 5 micrometer. The experimental findings were explained by the texture evolution model of Thompson and Carel. A significant observation which cannot be explained by a purely energetic argument is the broad texture transition. In order to get more information about the critical role of strain energy, uniaxial tensile tests were carried out on 3 micrometer thick films. In contrast to theoretical predictions, various tensile tests revealed no influence of strain on grain growth behaviour. Neither at room temperature nor at elevated temperatures, further (100) grain growth was observed. In a next step, the abnormal growth of individual (100) oriented grains was recorded for more than 24 hours at temperatures between 90 and 118°C. Annealing was carried out inside a Leo 1530-VP SEM equipped with a heating facility. Detailed analysis of grain growth and estimates of the possibly acting driving forces indicated that the reduction of dislocation density played an important role for abnormal grain growth. A further hint for the critical importance of defect density was given by the HWHM of the (100) texture fraction. Nevertheless, it was not clear why this driving force favours the growth of (100) oriented grains. A possible answer could be given by the strain energy release maximization (SERM) model developed by Lee. In addition, when analysing the activation energy for grain growth, they were found to possess a higher grain boundary mobility, supporting the preferred growth of (100) oriented grains. A new texture map, considering dislocation density as driving force, was constructed. Assuming dislocation density to play a significant role for grain growth and texture evolution in Cu thin films, the influence of deposition parameters is pointed out.
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    Deposition of metal oxide thin films from solutions containing organic additives
    (2007) Lipowsky, Peter; Aldinger, Fritz (Prof. Dr.)
    In bio-inspired materials synthesis the principles of biomineralization are employed for the fabri­cation of materials with favourable functional properties at near-ambient temperature and with little expenditure: Organic templates direct the formation of inorganic matter. In aqueous so­lu­tion, zinc compounds with manifold morphologies are produced by ther­mal hy­dro­ly­sis of zinc nitrate in the presence of biomolecules like amino acids and dipeptides. In methanol, ZnO films are deposited by hydro­lysis of zinc acetate in the presence of polymers like poly­vi­nyl­pyrro­li­done (PVP) and poly­ethylene glycol. With PVP, particularly smooth, uniform and stable films are fa­bri­cated. Their thickness is determined by the deposition time and the polymer concen­tration. Various microscopic and spec­tro­scopic mea­sure­ments prove that the films consist of textured na­no­cry­stal­line zinc oxide. Selected properties of the films, such as their photo­lumi­nescence, are in­ve­sti­gated. Film de­po­si­tion is possible on substrates with organic coatings bearing certain func­tio­nal groups. Pat­terned films can be de­po­si­ted after local de­com­po­si­tion of the or­ga­nic coating by UV light. The mecha­nism of film formation is treated in detail. Like in bio­mineralization, an amor­phous transient state of mat­ter occurs before crystallization. This state suc­cumbs to ZnO nano­crystals, which either aggregate in solution or adsorb to the substrate. It is de­mon­stra­ted in what way the additive controls the reaction. Sulfonate-mo­di­fied po­­ly­­sty­­rene beads are coa­ted with zinc oxide and used as sacrificial temp­lates for the fabrication of zinc oxide hollow spheres. La­mi­nates of alternating layers of zinc oxide and poly(amino acids) are deposited and ex­hibit an im­proved mechanical per­for­mance com­pared to the monolithic zinc oxide.
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    Aluminum-induced crystallization of semiconductor thin films
    (2015) Qu, Fei; Schmitz, Guido (Prof. Dr.)
    Thin film materials of the semiconductors, such as silicon (Si), germanium (Ge) or their alloys, are turning into the most promising functional materials in the energy technology. However, the morphologies of these semiconductor thin films must be varied to be suitable for the different applications, e.g. a large-grained layer as the seed layer of thin film solar cells, a porous structure for anode materials of high energy rechargeable lithium (Li) ion batteries. Due to the collective interdiffusion process during the aluminum (Al)-induced crystallization, in this thesis, the suitable morphologies are achieved for the corresponding applications under the different fabrication conditions. A large-grained Si layer can be formed by the crystallization of Si in a porous Al layer, which is obtained by applying a bias voltage. Since the Al grain boundaries are contaminated by e.g. oxygen (O), the diffusion of Si in the Al grain boundaries is retarded. It can lead to a reduction of the nucleation density of Si. At a certain high temperature, a collective diffusion process of Si in Al is activated. Consequently, a large-grained Si layer with (100) texture can be formed. By purposely interrupting the annealing of nanocrystalline Al/amorphous Si (a-Si) bilayers, a porous structure of the crystallized Si can be developed due to the incomplete intermixing of Si and Al. Due to the different dominant diffusion processes of Si in Al at the different annealing temperatures, the most Si diffuses along the different paths in the Al layer, such as triple junction, grain boundary and Al bulk. Therefore, it can develop the different morphologies of the porous Si layers after the selectively etching of Al. By introducing an amorphous Ge interlayer between the crystalline Al and amorphous Si layer, the Al grain boundaries are not essential for the crystallization of the amorphous Si in contrast to the case in Al/Si bilayer system. Si crystallizes continuously on the pre-crystallized Ge seeds which form initially at the original interface of crystalline Al and amorphous Ge. The thermodynamic models to interpret the fundamentals of these different crystallization behaviors of Si are established based on the change of the interface energy between the different phases of the whole system during the crystallization. Using the effective diffusivity, the dominant diffusion process of Si in Al can be investigated to explore the morphological dependence of the crystallized Si layer on the annealing conditions.
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    Template controlled mineralization of functional ZnO thin films
    (2017) Blumenstein, Nina; Bill, Joachim (Prof. Dr.)
    In this thesis, the influence of different organic templates on the bioinspired deposition of ZnO thin films is investigated. Depending on the polarity of the templates, the growth and the properties of the films can be influenced. On a non-polar template, film growth is inhibited whereas homogeneous films grow on polar templates. Additionally, it was shown that on a template with high polarity a crystallographic texture is observed. This leads to a macroscopically measurable piezoelectric response of these samples. In the last part of this work, the incorporation of Al, Ga and In into the ZnO films was investigated. Measurements showed a blue shift of the UV photoluminescence emission and an improved electrical conductivity with increasing doping content.
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    Microstructural changes and intermetallic compound formation in metallic bilayers
    (Stuttgart : Max-Planck-Institut für Intelligente Systeme (ehemals Max-Planck-Institut für Metallforschung), 2016) Rossi, Paul J.; Mittemeijer, Eric Jan (Prof. Dr. Ir.)
    This thesis investigates interdiffusion and intermetallic compound (IMC) formation, as well as their effects on the microstructure, in metallic thin-film bilayers. The investigation focuses on bilayers based on the Ag-Sn and Ag-In binary systems, which are technologically important as basis for lead free solders. Due to the enhanced diffusional mechanisms in these systems, diffusion occurs readily even at room and low temperatures. The proceeding interdiffusion eventually leads to IMC formation in the bilayers, allowing for the investigation of the kinetics of IMC formation and the associated microstructural changes at room and low temperatures. The combination of the properties special to thin films with the diffusional mechanisms in the binary Ag-Sn and Ag-In systems leads to interesting effects, such as the dependence of IMC formation on the stacking sequence in the bilayers. The obtained experimental results for both systems could be explained using thermodynamic and kinetic models. Experimental characterization of the bilayers mainly relied on X-ray diffraction (XRD) and electron microscopy. In order to investigate the effect of the deposition process on IMC formation and the microstructure of the bilayers, different physical vapor deposition (PVD) techniques, especially thermal evaporation and magnetron sputtering, were used for the preparation of the bilayers. During investigation of the Ag-Sn system it was found that ambiguity exists among the published crystal structures of the Ag3Sn IMC. Therefore, the crystal structure of Ag3Sn has been reinvestigated using high-resolution XRD in connection with Rietveld refinements.