2016
DOI: 10.1149/2.0501702jes
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Guidelines for the Rational Design and Engineering of 3D Manufactured Solid Oxide Fuel Cell Composite Electrodes

Abstract: The growth of 3D printing has opened the scope for designing microstructures for solid oxide fuel cells (SOFCs) with improved power density and lifetime. This technique can introduce structural modifications at a scale larger than particle size but smaller than cell size, such as by inserting electrolyte pillars of ∼5-100 μm. This study sets the minimum requirements for the rational design of 3D printed electrodes based on an electrochemical model and analytical solutions for functional layers with negligible … Show more

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Cited by 23 publications
(21 citation statements)
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References 71 publications
(167 reference statements)
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“…ASR corr /ASR plan ¼ 0.63 (see Table 1) and is equally associated to the contributions of the electrolyte and the electrodes. Therefore, one can clearly conclude that the increase of area by corrugation has an equivalent positive impact in both the electrolyte and the electrodes, which indicates that all the dominating phenomena are directly proportional to the area as theorized by other studies [42][43][44] (the same behaviour, with small variations in absolute values is maintained in all the temperature range).…”
Section: Solid Oxide Cells Performance In Fuel Cell and Co-electrolysis Modessupporting
confidence: 73%
“…ASR corr /ASR plan ¼ 0.63 (see Table 1) and is equally associated to the contributions of the electrolyte and the electrodes. Therefore, one can clearly conclude that the increase of area by corrugation has an equivalent positive impact in both the electrolyte and the electrodes, which indicates that all the dominating phenomena are directly proportional to the area as theorized by other studies [42][43][44] (the same behaviour, with small variations in absolute values is maintained in all the temperature range).…”
Section: Solid Oxide Cells Performance In Fuel Cell and Co-electrolysis Modessupporting
confidence: 73%
“…This geometry was especially designed to enable thinner membranes by using mechanically robust beams (shown in the SEM picture included in Figure 7a). Complementary, recent works have reported the benefits of incorporating geometrical patterns to increase the volumetric current density especially in the singularities [45] [46]. The thickness of the membrane was 260 μm (one fourth of the flat one) inside the hexagonal cells and ca.…”
Section: Resultsmentioning
confidence: 86%
“…Note that the current density is defined as the current divided not by the actual electrode-electrolyte interfacial areas but by the apparent geometrical cathode area for each tested cell. This is because the extended interfacial area in the patterned cells has complicated effects on the cell performance, some of which are strongly dependent on the size and shape of the mesostructure [14,32,33] and the thickness inhomogeneity. The OCVs of the cells at each operating temperature are very close to the theoretical values calculated from the Nernst equation, as shown in Table 3.…”
Section: Cell Structurementioning
confidence: 99%