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| Book/Dissertation / PhD Thesis | FZJ-2014-01851 |
2014
Forschungszentrum Jülich GmbH Zentralbibliothek, Verlag
Jülich
ISBN: 978-3-89336-950-8
Please use a persistent id in citations: http://hdl.handle.net/2128/9072
Abstract: Ionic transport in nanostructures at high field strength has recently gained attention, because novel types of computer memory with potentially superior properties rely on such phenomena. The applied voltages are only moderate, but they drop over the distance of a few nanometers and lead to extreme field strengths in the MV/cm region. Such strong fields contributes signicantly to the activation energy for ionic jump processes. This leads to an exponential increase of transport speed with voltage. Conventional high-temperature ionic conduction, in contrast, only relies on thermal activation for such jumps. In this thesis, the transport of minute amounts of oxygen through a thin dielectric layer sandwiched between two thin conducting oxide electrodes was detected semi-quantitatively by measuring the conductance change of the electrodes after applyinga current through the dielectric layer. The relative conductance change $\Delta$G/G as a function of current I and duration t follows over several orders of magnitude a simple, empirical law of the form $\Delta$G/G = CI$^{A}$t$^{B}$ with fit parameters C, A and B; A,B $\epsilon$ [0,1]. This empirical law can be linked to a predicted exponential increase of the transport speed with voltage at high eld strength. The behavior in the time domain can be explained with a spectrum of relaxation processes, similar to the relaxation of dielectrics. The influence of temperature on the transport is strong, but still much lower than expected. This contradicts a commonly used law for high-field ionic transport. The different oxide layers are epitaxial with thicknesses between 5 and 70 nm. First large-scale test samples were fabricated using shadow masks. The general behavior of such devices was studied extensively. In an attempt to achieve quantitative results with defect-free, miniaturized devices, a lithographic manufacturing process that uses repeated steps of epitaxial deposition and structuring of the layers was developed. It employs newly developed and optimized wet chemical etching processes for the conducting electrodes. First high-quality devices could be manufactured with this process and confirmed that such devices suffer less from parasitic effects. The lithographically structured samples were made from different materials. The results from the first test samples and the lithographically structured samples are therefore not directly comparable. They do exhibit however in principle the same behavior. Further investigation of such lithographically structured samples appears promising.
Keyword(s): Dissertation
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