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CMAS corrosion resistance of rare earth phosphates at high temperatures for environmental barrier coatings

Bishnu Pada Majee, Keith Bryce, Liping Huang, Jie Lian

2024Journal of the American Ceramic Society11 citationsDOIOpen Access PDF

Abstract

Abstract Phase stability, thermal properties, and calcium–magnesium–alumina–silicate (CMAS) resistance of LuPO 4 at 1300°C, 1400°C, and 1500°C were studied to evaluate its potential as an environmental barrier coating (EBC) for SiC‐based ceramic‐matrix composites (CMCs). Its coefficient of thermal expansion (∼5.69 × 10 −6 °C −1 ) is close to that of SiC‐based CMCs. At 1300°C, a dense reaction layer of Ca 8 MgLu(PO 4 ) 7 forms and inhibits CMAS penetration; however, no such layer forms at 1400°C and 1500°C, leading to CMAS infiltration along grain boundaries. Prolonged (45 and 96 hours) CMAS corrosion of LuPO 4 at 1300°C showed the formation of a disilicate (Lu 2 Si 2 O 7 ) phase along with Ca 8 MgLu(PO 4 ) 7 . A multicomponent rare earth phosphate (Lu 0.2 Yb 0.2 Er 0.2 Y 0.2 Gd 0.2 )PO 4 shows improved CMAS resistance at 1400°C due to higher grain boundary stability and slower dissolution rate of rare earth elements into molten CMAS than single component rare earth phosphate. The mechanisms of CMAS corrosion and the kinetics of the formation of protective reaction layers in LuPO 4 and (Lu 0.2 Yb 0.2 Er 0.2 Y 0.2 Gd 0.2 )PO 4 were elucidated. Multicomponent design is needed to increase grain boundary stability and reduce dissolution rate into molten CMAS for REPO 4 ‐based EBCs.

Topics & Concepts

CorrosionDissolutionGrain boundaryMaterials scienceThermal stabilitySilicateCeramicCoatingRare earthMineralogyKineticsChemical engineeringMetallurgyMicrostructureComposite materialChemistryQuantum mechanicsEngineeringPhysicsAdvanced ceramic materials synthesisNuclear materials and radiation effectsMagnesium Oxide Properties and Applications
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