As the AMA:Energy conference returns on April 30th to highlight qualified parts, real-world deployment, and energy-sector constraints, hydrogen production and storage technologies are becoming an increasingly prominent focus. Previous discussions pointed to the challenges of scaling electrolysis systems, particularly in relation to material limitations, system complexity, and long-term reliability. Within this context, ceramic additive manufacturing is being explored as a potential route to redesign solid oxide electrolysis systems, enabling new geometries and improved performance. 3DCeram Sinto is developing even further ceramic 3D printing technology for solid oxide electrolysis cells (SOECs), targeting improved hydrogen production and energy storage. The France-based company focuses on stereolithography (SLA)-based additive manufacturing, using a top-down process and low-viscosity ceramic slurries to enable scalable production of complex components.…