Litcius/Paper detail

Enhancing the Mechanical Strength of Electrolyte-Supported Solid Oxide Cells with Thin and Dense Doped-Ceria Interlayers

Matthias Riegraf, Ilaria Bombarda, Ferdinand Dömling, Tom Liensdorf, Carolin Sitzmann, Nico Langhof, Stefan Schafföner, Feng Han, Noriko Sata, Christian Geipel, Christian Walter, Rémi Costa

2021ACS Applied Materials & Interfaces22 citationsDOI

Abstract

The penetration of fuel cells and electrolyzers in energy systems calls for their scale-up to the gigawatt (GW) level. High temperature solid oxide cells (SOC) offer unrivaled efficiencies in both electrolysis and fuel cell operation. However, they are made of ceramics and are brittle by nature. Consequently, a high mechanical strength to avoid failure during stacking is essential to achieve a high manufacturing yield. Here, we show that without changing the materials of the state-of-the-art cells, thin and dense ceria interlayers enable comparable power densities and durability in fuel cell operation. The sole tuning of the morphology and processing of the interlayers reduce the residual stress in the cell significantly which increases its mechanical strength by up to 78%. These results promise performance gains of similar magnitude by enabling a substantial decrease of the electrolyte thickness while maintaining robustness. This stress engineering approach presents a way to increase the volumetric power density and material efficiency of SOC systems.

Topics & Concepts

Materials scienceBrittlenessElectrolyteDurabilityOxideCeramicPower densityComposite materialResidual stressElectrolysisElectrodePower (physics)MetallurgyPhysical chemistryChemistryQuantum mechanicsPhysicsAdvancements in Solid Oxide Fuel CellsChemical Looping and Thermochemical ProcessesElectronic and Structural Properties of Oxides