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Beilstein J. Nanotechnol. 2019, 10, 157–167, doi:10.3762/bjnano.10.15
Figure 1: Selected oxygen evolution activities for planar state-of-the-art electrode materials (adapted from ...
Figure 2: Pourbaix diagram for ruthenium in the presence of water (adapted from the Atlas of Eh-pH diagrams, ...
Figure 3: Photographs and schematic drawings of laser-induced chemical liquid deposition geometry on planar (...
Figure 4: SEM images of planar samples coated with laser-induced Ru/C films in cross-section (a) and top-view...
Figure 5: Preparation of nanostructured Ru/C electrodes. (a) Anodization of Al in 1 wt % H3PO4; this step def...
Figure 6: Scanning electron micrographs of a nanostructured Ru/C sample after all preparation steps in top vi...
Figure 7: Raman spectra of a nanostructured template coated with Ru/C films, without ITO contact (a) and of t...
Figure 8: X-ray photoelectron spectra of a nanostructured Ru/C sample recorded as deposited and after Ar+ spu...
Figure 9: Cyclic voltammograms of Ru/C electrodes recorded in a KH2PO4 electrolyte at pH 4 (scan rate: 50 mV s...
Figure 10: J–t curve of the same nanoporous (blue line) and planar (green line) electrode (as presented in Figure 7) d...
Figure 11: Tafel plots of nanoporous Ru/C electrodes of various lengths 11 ≤ L ≤ 24 μm in quasi-steady-state c...
Figure 12: Current densities of Ru/C electrodes for water oxidation measured at pH 4 and at 0.10 V or 0.20 V a...