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3D-Ceramic Architectures & Assemblies
Revolutionizing Eenrgy Technologies with Avanced Manufacturing
Revolutionizing Eenrgy Technologies with Avanced Manufacturing
Our cutting-edge product focuses on revolutionizing the manufacturing process of Solid Oxide Cells (SOCs) through innovative 3D structural design and advanced catalyst development. By combining state-of-the-art additive manufacturing and high-throughput materials synthesis, we are pushing the boundaries of electrocatalytic performance and energy conversion technologies.
🔹 Develop advanced 3D manufacturing techniques for complex ceramic solid oxide cell structures
🔹 Explore and optimize the relationship between 3D structural design and electrocatalytic activity
🔹 Create novel catalyst materials using high-throughput fabrication methods
🔹 Enhance the performance and understanding of electrolyte-supported solid oxide cell
Planning a cutting-edge membrane or electrode?
Let us bring your vision to life with our custom manufacturing expertise. Your innovation is our mission—partner with us and make your ideas a reality
Additively manufactured polymer, particles in a polymer matrix, and ceramic, containing internal microchannels and holes, to large-area over 50 mm.
🔹 Precise 3D structural engineering of solid oxide cells
🔹 High-throughput catalyst material development
🔹 Advanced manufacturing techniques
🔹 Fundamental insights into electrocatalytic performance
Bridging cutting-edge research and transformative technological innovation
Our Products
Our Products
Our technology enables the precise fabrication of multiscale ceramic membranes and oxide electrodes with enhanced performance. By leveraging additive manufacturing and film deposition, we create high-surface-area structures optimized for solid oxide fuel cells, thermoelectrics, and advanced electrochemical applications.
Ceramic
Octet Truss
Ceramic/Hydrogel
Plate / Wall / Hole
Metal Oxide/Hydrogel
Octet 3x3
Hydrogel
Octet 3x1
Membrane, Electrode, and Membrane-Electrode Assembly
Membrane, Electrode, and Membrane-Electrode Assembly
Digital Light Processing (DLP)-based 3D printing technology enables the precise fabrication of multiscale ceramic membranes and oxide electrodes with enhanced performance. By leveraging additive manufacturing and film deposition, we create high-surface-area structures optimized for solid oxide fuel cells, thermoelectrics, and advanced electrochemical applications.
Electrochemical / Thermoelectric Energy Applications
Electrochemical / Thermoelectric Energy Applications
🔹 Solid Oxide Fuel Cells (SOFCs) – Enabling efficient energy conversion at lower temperatures
🔹 Electrochemical Devices – High-performance electrodes for next-generation energy systems
🔹 Gas Sensors & Catalysis – Functional ceramic architectures for improved sensitivity
🔹 Catalytic Combustion – Stable operation and good heat transfer to the emitter
References
D. H. Kim, S.-H. Nam, G. Han, S. R. Park, G. H. Jeong, S. Kim, Y. T. Cho, "Robust catalyst 3D microarchitectures by digital light printing with ceramic particle-polymer composites," APL Materials 12(2), 021129 (2024).
G. Yang, S.-H. Nam, G. Han, N. X. Fang, and D. Lee, "Achieving Fast Oxygen Reduction on Oxide Electrodes by Creating 3D Multiscale Micro-Nano Structures for Low-Temperature Solid Oxide Fuel Cells," ACS Appl. Mater. Interfaces 15, 50427-50436 (2023).
S. Kim, S.-H. Nam, S. Kim, Y. T. Cho, and N. X. Fang, "Low Heat Capacity 3D Hollow Microarchitected Reactors for Thermal and Fluid Applications," Energies 15 (11), 4073 (2022).
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