# Ultra-High Strength and Specific Strength in Ti61Al16Cr10Nb8V5 Multi-Principal Element Alloy: Quasi-Static and Dynamic Deformation and Fracture Mechanisms

**Authors:** Yang-Yu He, Zhao-Hui Zhang, Yi-Fan Liu, Yi-Chen Cheng, Xiao-Tong Jia, Qiang Wang, Jin-Zhao Zhou, Xing-Wang Cheng

PMC · DOI: 10.3390/ma18143245 · 2025-07-10

## TL;DR

This paper studies a titanium-based alloy with high strength and explores how it deforms and fractures under different compression speeds.

## Contribution

The study reveals unique deformation mechanisms in a Ti61Al16Cr10Nb8V5 alloy under quasi-static and dynamic conditions.

## Key findings

- The alloy shows a strain-rate-strengthening effect with a sensitivity coefficient of ~0.0088 at low strain rates.
- At higher strain rates, the alloy activates additional slip planes and increases its sensitivity to strain rate.
- The alloy resists adiabatic shear localization and forms recrystallized shear bands through dynamic recrystallization.

## Abstract

This study investigates the deformation and fracture mechanisms of a Ti61Al16Cr10Nb8V5 multi-principal element alloy (Ti61V5 alloy) under quasi-static and dynamic compression. The alloy comprises an equiaxed BCC matrix (~35 μm) with uniformly dispersed nano-sized B2 precipitates and a ~3.5% HCP phase along grain boundaries, exhibiting a density of 4.82 g/cm3, an ultimate tensile strength of 1260 MPa, 12.8% elongation, and a specific strength of 262 MPa·cm3/g. The Ti61V5 alloy exhibits a pronounced strain-rate-strengthening effect, with a strain rate sensitivity coefficient (m) of ~0.0088 at 0.001–10/s. Deformation activates abundant {011} and {112} slip bands in the BCC matrix, whose interactions generate jogs, dislocation dipoles, and loops, evolving into high-density forest dislocations and promoting screw-dominated mixed dislocations. The B2 phase strengthens the alloy via dislocation shearing, forming dislocation arrays, while the HCP phase enhances strength through a dislocation bypass mechanism. At higher strain rates (960–5020/s), m increases to ~0.0985. Besides {011} and {112}, the BCC matrix activates high-index slip planes {123}. Intensified slip band interactions generate dense jogs and forest dislocations, while planar dislocations combined with edge dislocation climb enable obstacle bypassing, increasing the fraction of edge-dominated mixed dislocations. The Ti61V5 alloy shows low sensitivity to adiabatic shear localization. Under forced shear, plastic-flow shear bands form first, followed by recrystallized shear bands formed through a rotational dynamic recrystallization mechanism. Microcracks initiate throughout the shear bands; during inward propagation, they may terminate upon encountering matrix microvoids or deflect and continue when linking with internal microcracks.

## Full-text entities

- **Diseases:** Fracture (MESH:D050723), dislocations (MESH:D004204)
- **Chemicals:** Ti61Al16Cr10Nb8V5 (-), B2 (MESH:C023970)

## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12298045/full.md

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Source: https://tomesphere.com/paper/PMC12298045