Abstract
High-temperature processes for hydrogen production unlock the potential for high energy efficiency combined with a relatively low environmental impact. However, structural integrity should be carefully considered. Solid oxide electrolysis cells (SOEC) employ a range of ceramic and metallic materials capable of withstanding high temperatures, ranging from 500 degrees C to 1000 degrees C, while facilitating active electrochemical reactions. The present structural analysis focuses on the challenge of anticipating the formation of debonding cracks at the interfaces of layers (assumed non-porous) within a single SOEC cell with a tubular design and a metal support. This study includes implementation of material properties for ceramic mixtures, model verification, analysis of deformation, stresses, crack formation using the cohesive zone model (CZM) - a method commonly used to simulate the process of crack initiation and propagation. In this pioneering research, several potential areas of debonding have been identified, with the primary concentration occurring around the fixed-end boundaries. Findings reveal a temperaturedependent curvature for the maximum expected total deformations, where a linear growth pattern turns into a random pattern, peaking at 750 degrees C. Up to eight deformation zones, which could potentially serve as crack initiation locations, are identified near the fixed boundaries, and up to four zones are indicated by deformation contours for the main body of the tubular cell model. The study establishes and reports the evolution of these debonding zones through the high-temperature operating range.