Abstract

Freeze casting is a technique used to manufacture porous ceramics with aligned microstructures. In conventional freeze casting, these microstructures are aligned along a single direction of freezing. However, a caveat to these ceramics has been their ensuing lack of strength and toughness due to their high porosity, especially in the direction orthogonal to the direction of alignment. In this work, a novel freezing casting method referred to as “radial-concentric freeze casting” is presented, which takes its inspiration from the radially and concentrically aligned structure of the defensive spines of the porcupine fish. The method builds off the radial freeze casting method, in which the microstructure is aligned radially, and imposes a concentric alignment. Axial compression and Brazilian tests were performed to obtain axial compressive strengths, axial compressive moduli, and splitting tensile strengths of freeze cast samples with and without epoxy infiltration. Notably, radial-concentric freeze cast samples had the greatest improvements in axial compressive modulus and splitting tensile strength with infiltration, when compared against the changes in mechanical properties of conventional and radial freeze cast ceramics with infiltration. These results provide further evidence for the importance of structure in multiphase materials and the possibility of enhancing mechanical properties through the controlled alignment of microstructures.

Highlights

  • Freeze casting was introduced as early as the mid-20th century for technical applications requiring the use of refractory materials

  • Figure ceramic particles suspended within water, in contact with the freezing surface before cooling ceramic particles suspended within water, in contact with the freezing surface before coolingis thethe freezing surface begins, andand ice crystals beginbegin to form at theat freezing surface

  • Between samples produced through the three freeze casting methods

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Summary

Introduction

Freeze casting was introduced as early as the mid-20th century for technical applications requiring the use of refractory materials. The method uses the directional freezing of a colloidal suspension to produce a material with a controlled microstructure. As solvent crystals grow from one end of a suspension to another, particles become packed in between individual crystal arms, as shown in Ceramics 2019, 2, 15; doi:10.3390/ceramics2010015 www.mdpi.com/journal/ceramics. Packingofofceramic ceramicparticles particlesininbetween betweenice icecrystals crystalsduring duringfreeze freezecasting. Figure ceramic particles (green) suspended within water, in contact with the freezing surface before cooling ceramic particles (green) suspended within water, in contact with the freezing surface before coolingis thethe freezing surface begins, andand ice crystals beginbegin to form at theat freezing surface. Coolingofof freezing surface begins, ice crystals to form the freezing (C) Figure ceramic particles (green) suspended within water, in contact with the freezing surface before cooling ceramic particles (green) suspended within water, in contact with the freezing surface before coolingis thethe freezing surface begins, andand ice crystals beginbegin to form at theat freezing surface. isapplied. applied.(B) (B)Cooling

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