Aluminum-doped ZnO (AZO) thin films were produced via template-directed deposition at 60 °C. By adding organic molecules to the deposition solution, it is possible to control the crystallite growth, and nanocrystallinity is achieved. An organic template, 3-aminopropyltriethoxysilane (APTES), is used to direct the attachment of the crystallites on the substrate. The optical properties and the incorporation of the aluminum from solution into the ZnO films were measured using photoluminescence (PL) and inductively coupled plasma atomic emission spectroscopy (ICP-AES). The morphology of the film was investigated using scanning electron microscopy (SEM) and X-ray diffraction (XRD). The latter revealed a preferred orientation of the crystallites in the samples where more than 15 mol% Al was added to the stock solution.For values higher than 30 mol% Al in solution, no ZnO was found at all.
We study the particle formation process of Zirconia ( ZrO 2 )-based material. With a model-based description of the particle formation process we aim for identifying the main growth mechanisms for different process parameters. After the introduction of a population balance based mathematical model, we derive the moment dynamics of the particle size distribution and compare the model to experimental data. From the fitted model we conclude that growth by molecular addition of Zr-tetramers or Zr-oligomers to growing particles as well as size-independent particle agglomeration takes place. For the purpose of depositing zirconia-based material (ZrbM) on a substrate, we determine the optimal process parameters such that the mineralization solution contains preferably a large number of nanoscaled particles leading to a fast and effective deposition on the substrate. Besides the deposition of homogeneous films, this also enables mineralization of nanostructured templates in a bioinspired mineralization process. The developed model is also transferable to other mineralization systems where particle growth occurs through addition of small molecular species or particle agglomeration. This offers the possibility for a fast determination of process parameters leading to an efficient film formation without carrying out extensive experimental investigations.
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