Litcius/Paper detail

First‐principles investigation of solution mechanism of C in TM‐Si‐C matrix as the potential high‐temperature ceramics

Delin Pu, Yong Pan

2021Journal of the American Ceramic Society77 citationsDOI

Abstract

Abstract Although the TM‐Si‐C ternary compounds are promising advanced ceramics, the solution mechanism of C element in TM‐Si matrix is entirely unclear. In particular, the influence of C on the mechanical properties of TM‐Si matrix is no clear. To solve the problem, we apply the first‐principles calculations to study the occupied mechanism of C in TM 5 Si 3 silicides. In addition, the influence of C element on the mechanical properties of TM 5 Si 3 is further studied. Here, two typical TM 5 Si 3 phases: D8 l ‐Ta 5 Si 3 and D8 m ‐Mo 5 Si 3 are considered. For C‐doping, six C interstitial sites, Mo 5 Si 3 ‐C(1), Mo 5 Si 3 ‐C(2), Mo 5 Si 3 ‐C(3), Ta 5 Si 3 ‐C(1), Ta 5 Si 3 ‐C(2), and Ta 5 Si 3 ‐C(3), are designed. The calculated results show that six C‐doped TM 5 Si 3 matrices are thermodynamically stable. Among them, the C element prefers to occupy the Mo 5 Si 3 ‐C(2) and Ta 5 Si 3 ‐C(3) models. The calculated mechanical properties show that the additive C element weakens the bulk modulus, shear modulus, and Young's modulus of TM 5 Si 3 . However, the C element can improve the fracture toughness of Mo 5 Si 3 and Ta 5 Si 3 , which are in good agreement with the experimental phenomenon. Naturally, the improvement of fracture toughness is related to the formation of TM‐C bond and Si‐C bond.

Topics & Concepts

Materials scienceFracture toughnessTernary operationCeramicDopingMAX phasesShear modulusModulusBulk modulusComposite materialCrystallographyChemistryOptoelectronicsProgramming languageComputer scienceMXene and MAX Phase MaterialsAdvanced ceramic materials synthesisAdvanced materials and composites