Microstructural evolution and energetic characteristics of TiZrHfTa0.7W0.3 high-entropy alloy under high strain rates and its application in high-velocity penetration

doi:10.1016/j.jmst.2022.05.043

Abstract

Abstract:

Energetic structural materials (ESMs) integrated a high energy density and rapid energy release with the ability to serve as structural materials. Here, a novel triple-phase TiZrHfTa_0.7W_0.3 high-entropy alloy (HEA) was fabricated and investigated as a potential ESM. A hierarchical microstructure was obtained with a main metastable body-centered-cubic (BCC) matrix with distributed Ta-W-rich BCC precipitates of various sizes and interwoven hexagonal close-packed (HCP) lamellar nano-plates. The compressive mechanical properties were tested across a range of strain rates and demonstrated a brittle-to-ductile transition as the strain rate increased while maintaining a high ultimate strength of approximately 2.5 GPa. This was due to the phase transformation from metastable matrix BCC to HCP structures. In addition, during the dynamic deformation, metal combustion originating from the failure surface was observed. Furthermore, the composition of the fragments was studied, and the results indicated that the addition of tungsten promoted combustion. Finally, the potential application of this HEA was evaluated by high-velocity penetration tests, and the results were compared to other typical structural materials for penetrators and bullets. A comparison was conducted by assessing the geometries of the penetration channel employing two dimensionless parameters normalized by the projectile size, representing longitudinal and lateral damage, respectively. The normalized depth of the TiZrHfTa_0.7W_0.3 HEA projectile was comparable to those of the other investigated materials, but the normalized diameter was the largest, showing an excellent ability to deliver lateral damage.

Key words: Energetic structural materials, High-entropy alloys, Phase transformation, Ballistic tests

Weiqi Tang, Kun Zhang, Tianyu Chen, Qiu Wang, Bingchen Wei. Microstructural evolution and energetic characteristics of TiZrHfTa_0.7W_0.3 high-entropy alloy under high strain rates and its application in high-velocity penetration[J]. J. Mater. Sci. Technol., 2023, 132: 144-153.

Figures/Tables 10

Fig. 1. (a) Gaseous-detonation driven ballistic range DBR30 device and (b) experimental layout for the penetration tests.

Fig. 2. (a) XRD pattern of the as-cast TiZrHfTa0.7W0.3 sample, (b) grain size distribution with the region in (c), (c) EBSD IPF map, (d) phase map.

Fig. 3. (a) BSE image near the grain boundary and (b) SEM-EDS element distribution of the red dashed region in (a).

Fig. 4. (a) Selected area of the FIB-TEM sample and corresponding SAED patterns of the precipitates and the matrix; (b) TEM-EDS maps of the red region in (a) and the corresponding fast Fourier transform patterns of the BCC1 and HCP matrix.

Fig. 5. Compressive mechanical properties at various strain rates of the TiZrHfTa0.7W0.3 HEA: (a) engineering stress-strain compression curves; (b) yield strength (YS), ultimate strength (US), and fracture strain (FS); (c) corresponding strain hardening rates.

Fig. 6. High-speed photographs during Hopkinson bar impact tests ($\dot{\mathcal{\varepsilon}}$= 4200 s?1), where the sample failed at 50 μs, and metal combustion was observed along the fractured surface.

Fig. 7. (a) Remnant fracture surface at 4200 s?1. Red circles mark a large number of molten particles, and the two red lines (denoted as b and c) in the yellow region are for the EDS line scanning; (b, c) corresponding EDS line profiles for lines b and c in (a), respectively.

Fig. 8. XPS spectra of Ti, Zr, Hf, Ta, and W elements on the fracture surface at 4200 s?1 and the percentage of metals and metal oxides.

Fig. 9. High-speed video frames of the penetration process of TiZrHfTa0.7W0.3 HEA projectiles: (a) with optical filters and background light source, (b) without optical filters and background light source.

Fig. 10. (a) Cross-section of the target plate with YL10.2 alloys (left), HEA in this study (middle), and 18Ni stainless steel (right) cylindrical projectiles; (b) hole diameter vs. depth diagram, and the inset is the volume of penetration channel; (c) relationship of kinetic energy with P/L; (d) relationship of kinetic energy with D*/Dpro.

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