Traditional additive manufacturing (AM) of ceramic parts is performed using indirect processes that require a polymeric binder to fuse ceramic powder particles layer by layer. Post processing consists of pyrolysis of the polymeric binder before sintering the parts to full density. The pyrolysis step can be extremely slow and challenging for the production of large ceramic parts. Direct AM of ceramic parts without polymer binder has been attempted, but is challenging because of the slow sintering kinetics, high melting temperatures, high Young’s modulus and poor fracture toughnesses of ceramics that leads to cracking.
Selective laser flash sintering (SLFS) is a recently invented process that utilizes a scanning laser combined with an electric field to lower the required temperatures and speed the sintering kinetics significantly so that direct laser sintering may be possible. We are conducting research to understand the mechanisms that control SLFS. This project is supported by the Office of Naval Research.
Faculty Members
- Desiderio Kovar
- Joseph Beaman
Graduate Student Researchers
- Deborah Hagen
- Lezli Matto Gonzales
- David Khanan