What does this research mean for the field?

In the 27.3Ta-27.3Mo-27.3Ti-8Cr-10Al high-entropy alloy, creep deformation mechanisms transition from dislocation climb at low stresses to cross slip at high stresses, while maintaining a fully coherent A2/B2 interface and exhibiting plate-like B2 raft formation. Novelty: ClaimNovelty.INCREMENTAL. Consensus alignment: ConsensusAlignment.SUPPORTS_CONSENSUS.

What question did this study set out to answer?

This research aims to understand how creep affects the microstructure of a specific high-entropy alloy at high temperatures. It focuses on the mechanisms involved in dislocation interactions and precipitate behavior during deformation.

June 1, 2026Open Access

Creep‐Induced Microstructural Evolution in an A2‐B2 Superalloy

Key Points

This research aims to understand how creep affects the microstructure of a specific high-entropy alloy at high temperatures. It focuses on the mechanisms involved in dislocation interactions and precipitate behavior during deformation.
Examined a high-entropy alloy with an A2-B2 microstructure under varying stress conditions.
Employed focused ion beam-based 3D sectioning to identify the geometry of B2 precipitates.
Utilized electron backscatter diffraction and transmission electron microscopy to analyze dislocation and precipitate interactions.
B2 precipitates exhibited a plate-like shape and were not observable through conventional imaging methods.
At low stresses, dislocation climb was observed, while at high stresses deformation involved cross slip of screw dislocations.
The A2/B2 interface remained coherent throughout all tested creep conditions, ensuring structural stability.

Abstract

The refractory element‐based 27.3Ta‐27.3Mo‐27.3Ti‐8Cr‐10Al (at.%) high‐entropy alloy with a precipitation‐strengthened A2‐B2 microstructure exhibits substantial B2 raft formation and a transition in apparent creep exponent near 125 MPa at 1030°C. Using focused ion beam‐based 3D sectioning, the B2 precipitates were identified as having a plate‐like geometry, characterized by elongation on two orthogonal cut faces and faceting on the third face, a morphology that cannot be resolved by conventional 2D imaging. Electron backscatter diffraction analysis reveals the formation of low‐misorientation subgrain structures, consistent with dynamic recovery processes. Transmission electron microscopy (TEM) analyses reveal a change in dislocation–precipitate interaction with increasing applied stress. At low stresses, dislocation climb is confirmed, whereas at high stresses, deformation is likely associated with cross slip of screw dislocations. In the intermediate stress range, deformation is characterized by a combination of climb‐controlled dislocation–precipitate interaction, jogged‐screw dislocations, and the cutting of B2 precipitates by strongly coupled dislocation pairs. High‐resolution scanning TEM further confirms that the A2/B2 interface remains fully coherent across all creep conditions examined, maintaining structural stability under high‐temperature deformation.

Creep‐Induced Microstructural Evolution in an A2‐B2 Superalloy

Key Points

Abstract

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