Scientists at the US Department of Energy’s Oak Ridge National Laboratory have integrated binder jet additive manufacturing with an advanced post-processing method to fabricate leak-tight ceramic components, overcoming a key challenge of ceramic AM.
While ceramic components perform exceptionally well in extreme environments – exhibiting high temperature resistance, chemical stability, and mechanical strength – current methods of ceramic 3D printing fall short on scalability. This shortcoming limits their use in critical applications such as high-throughput chemical reactors, which are used for pharmaceutical or chemical processing, where large, leak-proof parts are essential. ORNL’s solution provides a scalable method for creating complex ceramic structures by leveraging a robust joining technique that enables smaller 3D printed pieces to be assembled to create the needed components.
“Ceramic 3D printing allows fabrication of intricate and high-performance components that are difficult to achieve with traditional manufacturing methods,” said lead researcher Trevor Aguirre from ORNL’s Extreme Environment Materials Process Group. “This advancement provides a validated methodology to produce high-quality components – and enable the development of next-generation reactors.”
The research team tested multiple design configurations to identify optimal structures that inherently support gas-tight integrity and developed post-processing techniques to enhance the bonding and sealing of ceramic segments.
Not only does the innovation help meet the increasing demand for large-scale components, but it also leverages cost-efficient binder jet AM. This method offers substantial economic benefits and paves the way for broader industrial adoption of ceramic AM in other high-performance applications, such as aerospace, among others. The work, titled “Binder Jet Additive Manufacturing (BJAM) of Silicon Carbide Reactor Assemblies for High-Temperature and Hydrogen Leak-Tight Applications,” can be found here.
This is one of the first known leak-tight joints fabricated using AM methods.
The ORNL team received SME’s 2025 Dick Aubin Distinguished Paper Award for this research, which recognizes significant contributions to AM. The team also has related research published in the Ceramics International journal.
*This article originally appeared on VoxelMatters. Edward Wakefield is the original author of this piece.
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