Litcius/Paper detail

Spallation damage of 90W–Ni–Fe alloy under laser-induced plasma shock wave

Lei Zhang, Yufeng Huang, Hua Shu, Baishan Chen, Xun Chen, Yunzhu Ma, Wensheng Liu

2022Journal of Materials Research and Technology16 citationsDOIOpen Access PDF

Abstract

Laser shock loading is a more promising technology for investigating spallation damage in materials under shock-wave loading. In this paper, shock-induced spallation in a 90W–Ni–Fe alloy at an ultrahigh tensile strain rate of 106 s−1 is investigated using a superintense ultrafast laser facility. The spallation of the 90W–Ni–Fe alloy was dominated by a transgranular fracture of tungsten(W) particles with a high spall strength of 6.46 GPa. Here, we found an interesting phenomenon that the formation of nanograins inside W particles leads to a new mode of transcrystalline fracture of W particles during the laser shock loading. Futhermore, most voids were nucleated inside the W particles rather than at the W/γ-(Ni, Fe) matrix-phase interface. This result contradicts the fracture theory under quasi-static loading, which posits that the W/γ-(Ni, Fe) matrix-phase interface is not the preferred site for the initial failure under shock loading.

Topics & Concepts

Materials scienceSpallationSpallShock (circulatory)AlloyShock waveComposite materialLaserPhase (matter)Ultimate tensile strengthFracture (geology)MetallurgyOpticsMechanicsNeutronNuclear physicsOrganic chemistryChemistryMedicineInternal medicinePhysicsIon-surface interactions and analysisSurface Treatment and Residual StressHigh-Velocity Impact and Material Behavior