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Computational Discovery of the Qualitative Electronegativity–Wettability Relationship in High-Temperature Ceramics-Supported TiAl Alloys

Yapeng Zheng, Zhi Fang, Qian Sun, Enhui Wang, Minghui Shang, Weiyou Yang, Xinmei Hou

2022The Journal of Physical Chemistry C16 citationsDOI

Abstract

The inevitable interaction between high-temperature ceramics (HTCs) and molten TiAl alloys during the casting process tends to cause the increased oxygen concentration, fracture, and embrittlement within TiAl alloys, and the interaction is closely related to wettability. Herein, the underlying mechanism of wettability (i.e., contact angle) between HTCs and molten TiAl alloys is systematically investigated by molecular dynamics (MD) simulations. Taking the interaction between the common adopted crucible (i.e., BaZrO3, Y2O3, ZrO2, and Al2O3) and molten TiAl alloys, for example, the calculated contact angles between γ-TiAl and HTCs decrease in the sequence of BaZrO3, Y2O3, ZrO2, and Al2O3 and with the Ti content of TiAl alloys increasing. This is in agreement with the experimental results, verifying the feasibility of MD simulations. In addition, based on MD simulations, the electronegativity of metal elements within HTCs decreases in the order of Al2O3, ZrO2, Y2O3, and BaZrO3, which further discloses the relationship between electronegativity and wettability, i.e., smaller electronegativity of metal elements leads to worse wettability of HTCs. This might push forward the design of HTCs with better stability, such as BaZrO3 doped by Hf, Y, lanthanide, or actinide elements and BaHfO3.

Topics & Concepts

ElectronegativityWettingMaterials scienceContact angleCeramicMetallurgyLanthanideCrucible (geodemography)ThermodynamicsCrystallographyComposite materialChemistryComputational chemistryIonPhysicsOrganic chemistryIntermetallics and Advanced Alloy PropertiesAdvanced ceramic materials synthesisMXene and MAX Phase Materials