Litcius/Paper detail

Revealing the solid-state reaction process among multiphase multicomponent ceramic during ablation

Ziming Ye, Yi Zeng, Xiang Xiong, Sen Gao, Chen Shen, Shiyan Chen, Tianxing Jiang, Yang Ge

2024Advanced Powder Materials21 citationsDOIOpen Access PDF

Abstract

Multiphase design is a promising approach to achieve superior ablation resistance of multicomponent ultra-high temperature ceramic (UHTC), while understanding the ablation mechanism is the foundation. Here, through investigating a three-phase multicomponent ceramic consisting of Hf-rich carbide, Nb-rich carbide, and Zr-rich silicide phases, we report a newly discovered solid-state reaction process among multiphase multicomponent ceramic during ablation. It was found that this solid-state reaction occurred in the matrix/oxide scale interface region. In this process, metal cations are counter-diffused between the multicomponent phases, thereby resulting in their composition evolution, which allows the multicomponent phases to exist stably under a higher oxygen partial pressure, leading to the improvement of thermodynamic stability of three-phase multicomponent ceramic. Additionally, this solid-state reaction process appears synergistic with the preferential oxidation behavior among the oxide scale in enhancing the ablation performance.

Topics & Concepts

CeramicMaterials scienceCarbidePhase (matter)OxideChemical engineeringCeramic matrix compositeAblationSolid-stateThermodynamicsComposite materialPhysical chemistryMetallurgyChemistryOrganic chemistryPhysicsEngineeringAerospace engineeringAdvanced materials and compositesAdvanced ceramic materials synthesisMXene and MAX Phase Materials
Revealing the solid-state reaction process among multiphase multicomponent ceramic during ablation | Litcius