Publications by authors named "Sandra Haschke"
For the oxidation of water to dioxygen, oxide-covered ruthenium metal is known as the most efficient catalyst, however, with limited stability. Herein, we present a strategy for incorporating a Ru/C composite onto a novel nanoporous electrode surface with low noble metal loading and improved stability. The Ru/C is coated on the pore walls of anodic alumina templates in a one-step laser-induced deposition method from Ru(CO) solutions.
View Article and Find Full Text PDFUnderstanding the mechanism of water oxidation to dioxygen represents the bottleneck towards the design of efficient energy storage schemes based on water splitting. The investigation of kinetic isotope effects has long been established for mechanistic studies of various such reactions. However, so far natural isotope abundance determination of O produced at solid electrode surfaces has not been applied.
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- * The electrodes are created by coating the templates with metallic iridium through a method called atomic layer deposition (ALD), and their properties are analyzed using various techniques like electron microscopy and X-ray spectroscopy.
- * The research shows that with optimal pore lengths of about 17-20 μm, these electrodes can achieve significant current densities at different pH levels, making them promising for efficient energy storage applications.
Nanotubular iron(III) oxide electrodes are optimized for catalytic efficiency in the water oxidation reaction at neutral pH. The nanostructured electrodes are prepared from anodic alumina templates, which are coated with Fe O by atomic layer deposition. Scanning helium ion microscopy, X-ray diffraction, and Raman spectroscopy are used to characterize the morphologies and phases of samples submitted to various treatments.
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