Mechanical properties and failure behaviour of architected alumina microlattices fabricated by stereolithography 3D printing

Alumina microlattices with solid struts and different topologies were fabricated by the stereolithography 3D printing method. Mechanical analysis shows that specific stiffness and strength were highest for Simple Cubic lattices, followed by Octet Truss, then Kelvin Cell lattices. The mechanical properties followed Ashby's power law well at small relative densities (<= 0.3), but deviated from it at higher relative densities due to the increased importance of joint deformation. Failure in the Simple Cubic lattices proceeded in a column-by-column manner from the boundaries inwards to the centre, while fracture in Octet Truss and Kelvin Cell lattices took place predominantly along the diagonal (111) and (110) planes respectively. The underlying mechanism controlling these mechanical responses has been thoroughly discussed using finite element simulation analysis. Because lattice strength was limited by the tensile strength of alumina, which was an order of magnitude lower than its compressive strength, the microlattices were weaker than Ashby's predictions. Nevertheless, they were still able to exhibit better specific modulus and strength than many current engineering materials, as well as some degree of ductility in the form of pseudoplastic strains (0.1 % - 0.5 %).

Automated summary

Alumina microlattices with different topologies were fabricated using stereolithography 3D printing method. The mechanical properties were highest in Simple Cubic lattices and deviated from Ashby's power law at higher relative densities due to joint deformation. Failure mechanisms were discussed using finite element simulation analysis, showing that the microlattices exhibited better specific modulus and strength than many engineering materials.