Simone Herzog scite author profile

Membrane-based oxy-combustion is a promising technology for energy efficient combustion of carboncontaining fuels with the simultaneous opportunity to capture CO2 from the resulting exhaust gas.However, oxy-combustion conditions result in special demands on the design of the ceramic membrane components due to the high pressure and temperature applied. Therefore, we have developed a planar membrane design for 4-end operation using asymmetric membranes of La0.6Sr0.4Co0.2Fe0.8O3-δ. FEM and CFD simulations have been performed in order to develop an internal channel structure that allows withstanding pressures of 5 bar on the feed side while achieving the desired O2 concentrations of 27 % in the sweep gas, i.e. CO2, and an oxygen recovery rate from the feed gas of 86 % at the same time.Due to the symmetric design of the membrane components, they are scalable and adaptable in size. This design has been realized in a process chain from powder to the final component consisting of thin 20 µm Membrane layer, support with 38 % porosity, an inner channelled architecture and a thin (3-5 µm) porous activation layer. Particular emphasis was laid on scalable manufacturing processes in order to ensure transferability to industrial scale. The process chain is also applicable to other membrane materials suitable for any application of interest. Finally, the reproducible processing was successfully demonstrated by the fabrication of membrane components in lengths of 100 mm and widths of 70 mm.

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Dzyaloshinskii–Moriya interaction in transport through single-molecule transistors

Herzog

Wegewijs

2010

Nanotechnology

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Abstract.The Dzyaloshinskii-Moriya interaction is shown to result in a canting of spins in a single molecule transistor. We predict non-linear transport signatures of this effect induced by spin-orbit coupling for the generic case of a molecular dimer. The conductance is calculated using a master equation and is found to exhibit a non-trivial dependence on the magnitude and direction of an external magnetic field. We show how three-terminal transport measurements allow for a determination of the couplingvector characterizing the Dzyaloshinskii-Moriya interaction. In particular, we show how its orientation, defining the intramolecular spin chirality, can be probed with ferromagnetic electrodes.

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Simone Herzog

Membrane module for pilot scale oxygen production

Influence of hot isostatic pressing post-treatment on the microstructure and mechanical behavior of standard and super duplex stainless steel produced by laser powder bed fusion

Design and fabrication of large-sized planar oxygen transport membrane components for direct integration in oxy-combustion processes

Dzyaloshinskii–Moriya interaction in transport through single-molecule transistors

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