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Miscible chemical ordering in Ti-Cr-Mo quinary system by solid solution of Mo2Ti2AlC3 and Cr2.5Ti1.5AlC3 o-MAXs

Cheng‐Feng Du, Chuan‐Chao Wang, M.K. Xu, Yaqing Xue, Lili Xue, Conghui Meng, Long Wang, Weihong Qi, Xuqing Liu, Hong Yu

2025Nature Communications15 citationsDOIOpen Access PDF

Abstract

Out-of-plane ordering is promising for separately adjusting the heterodesmic chemical bonding inside the MAX phase thus tuning their properties, while constructing the out-of-plane ordered-MAX (o-MAX) is still a challenge. In this work, a strategy towards o-MAX by solid solutions of two existing o-MAXs is verified, i.e., Cr2.5Ti1.5AlC3 and Mo2Ti2AlC3, with controllable stoichiometric ratios (1:2, 1:1, and 2:1). A miscible chemical ordering is observed in three Ti-Cr-Mo quinary MAXs, which inherits the out-of-plane ordering from both parental o-MAXs. Meanwhile, through density functional theory (DFT) calculations, the electronic structure and bonding states inside the quinary o-MAXs are analyzed. Based on the calculations, anisotropic and improved mechanical properties are predicted, which agree with the experimental observed high compressive strength and tunable capacity of energy dissipation. The present work proves a promising way for synthesizing multicomponent o-MAXs. The authors achieve a multicomponent out-of-plane-ordered MAX phase (o-MAX) by stoichiometrically mixing two existing o-MAXs, which inherits the chemical ordering from the originating phases and has adjustable properties, demonstrating a promising strategy for o-MAX construction.

Topics & Concepts

QuinarySolid solutionMaterials scienceChemistryMetallurgyAlloyMXene and MAX Phase MaterialsAdvanced materials and compositesIntermetallics and Advanced Alloy Properties
Miscible chemical ordering in Ti-Cr-Mo quinary system by solid solution of Mo2Ti2AlC3 and Cr2.5Ti1.5AlC3 o-MAXs | Litcius