Integrated manufacturing of REciclable multi-material COmposites for the TRANSport sector
Corrosion behavior of Al4SiC4/SiC ceramics exposed to molten calcium?magnesium?alumino?silicate at 1350°C in air
Al4SiC4 shows excellent heat resistance, thermal shock resistance, machinability, and oxidation resistance. We focused on Al4SiC4?based ceramics with SiC as a non?oxide matrix for ceramic matrix composites for aircraft jet engines. In this study, monolithic Al4SiC4 and Al4SiC4/SiC ceramics were fabricated by hot?pressing, and a corrosion test against molten calcium?magnesium?alumino?silicate (CMAS) was conducted at 1350°C for 12–100 h in air, and their corrosion behavior was investigated. Scanning electron microscopy and energy?dispersive X?ray spectroscopy results revealed that severe damage was not observed at the interface between CMAS and the samples after the CMAS corrosion test. The recession of Al4SiC4?100, ?10, and SiC?100 after corrosion for 100 h was 80–90 µm, and that of Al4SiC4?50 was the highest of all samples and the value was 130 µm. The dissolution behavior of the oxidation layer into molten CMAS via a corrosion reaction was dependent on the composition of both the sample and the oxidation layer, the thickness, and the microstructure of the oxidation layers. The dominant mechanism of reaction between CMAS and Al4SiC4?100, ?90, and ?50 samples was concluded to be the dissolution of the oxidation products, while in SiC?100 and Al4SiC4?10 samples, the dominant reaction was determined to be direct corrosion of the surface with CMAS.
» Publication Date: 11/04/2024
This project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement Nº 768737
