Litcius/Paper detail

3-D inkjet printed solid oxide electrochemical reactors III. Cylindrical pillared electrode microstructures

Nicholas M. Farandos, Inyoung Jang, John Callum Alexander, G. H. Kelsall

2022Electrochimica Acta10 citationsDOIOpen Access PDF

Abstract

Inkjet printing is a scalable technique that can fabricate customised three-dimensional microstructures, reproducibly, accurately, and with high material utilisation, by printing multiple layers sequentially onto previously printed layers, to produce architectures tailored in this case to electrochemical reactors. Printable yttria-stabilised zirconia (YSZ) and lanthanum strontium manganite (LSM) inks were formulated to enable fabrication of solid oxide electrochemical reactors (SOERs): H2O-H2 | Ni(O)-YSZ | YSZ | YSZ pillars | LSM | O2. Of the geometries studied, equi-sized, hexagonally-arranged cylindrical pillars were predicted to produce the largest ratio of interfacial to geometric (cross-sectional) areas. However, this neglects effects of potential and current density distributions that constrain up-scaling to more modest factors. Hence, using kinetic parameter values from the literature, finite element computational simulations of the pillared SOER in (H2 - O2) fuel cell mode predicted peak power densities of 0.11 W cm−2 at 800 °C, whereas its counterpart with only a planar electrolyte layer produced only 0.05 W cm−2; i.e. the pillars were predicted to enhance peak power densities by ca. 2.3. Arrays of several thousand YSZ cylindrical pillars were printed, with post-sintering diameter, height, and spacing of 25, 95 and 63 μm, respectively. LSM was inkjet-printed onto the pillars, and sintered subsequently, to produce contiguous films ca. 4 μm thick. In (H2 - O2) fuel cell mode at 725, 770, and 795 °C, these reactors produced peak power densities of 0.09, 0.21, 0.30 W cm−2, respectively, 3–6 times greater than the performance of ‘benchmark’ Ni(O)-YSZ | YSZ | LSM reactors inkjet-printed with planar cathodes operating under the same conditions, thereby demonstrating the benefit of inkjet printing as a fabrication technique for SOERs.

Topics & Concepts

Materials scienceYttria-stabilized zirconiaMicrostructurePower densitySolid oxide fuel cellElectrolyteOxideElectrochemistrySinteringTape castingScreen printingElectrodeFabricationPorosityComposite materialCurrent densityCubic zirconiaNanotechnologyChemical engineeringMetallurgyCeramicPower (physics)ChemistryPhysical chemistryPhysicsAlternative medicineEngineeringPathologyMedicineQuantum mechanicsAdvancements in Solid Oxide Fuel CellsElectronic and Structural Properties of OxidesElectrocatalysts for Energy Conversion