Ultrastrong and damage-tolerant ceramic architectures via 3D printing

Ceramic materials have high mechanical strength and exceptional environmental stability, but are suboptimal for structural applications due to their inherent brittleness and low damage tolerance. Here, we report ultrastrong and damage-tolerant ceramic architectures that are designed based on Schwarz Primitive structures and man-ufactured by digital light processing (DLP)-based 3D printing. Through micro-computed tomography imaging and in situ compression experiments, we reveal that the step effect of 3D printing plays a role in crack initiation and propagation of the 3D-printed architectures. When the loading direction is perpendicular to the printing direction, the steps can induce cracks to propagate along the loading direction, which is beneficial to localize the cracks in the outer part of structure and enhance the structural strength and damage tolerance. After optimizing structural design and heat treatment process, the printed ceramic architecture can achieve compressive strength as high as 710 MPa at a relative density of 57.58 %. More importantly, the printed ceramic architecture exhibits excellent damage tolerance. It can bear more 20 cycles of 6 % compressive strain when 28 % of the structures have been damaged. The ceramic architecture can still bear the load without failure even when the degree of damage reaches 44 %. The superior mechanical properties make them have great potential in engineering ap-plications that require high mechanical reliability.

Automated summary

Ultrastrong and damage-tolerant ceramic architectures designed based on Schwarz Primitive structures and manufactured by DLP-based 3D printing are reported. The step effect of 3D printing plays a role in crack initiation and propagation, enhancing the structural strength and damage tolerance. After optimization, the printed ceramic architecture achieves high compressive strength and excellent damage tolerance.