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<i>In situ</i> synchrotron imaging reveals interfacial-constraint-driven fracture transition in Ti/Al layered composites under dynamic tension

Zhuangzhuang Liu, Xinbo Ni, Qiang Zhu, Peng Zhang, Hao Wu, Guohua Fan

2025Materials Research Letters5 citationsDOIOpen Access PDF

Abstract

Interfacial constraints are critical for achieving the strength-ductility synergy in layered materials. However, their effectiveness under dynamic loading conditions remains insufficiently understood. In this study, we investigated the deformation behavior of Ti/Al layered composites under Hopkinson tensile loading using in situ synchrotron imaging. Our results demonstrate that the presence of interfaces continues to influence the fracture processes of the layered composite even at strain rates as high as 103 s−1, accompanied by a transition in the fracture mode from necking to 45° shear fracture in the Ti layers. These findings significantly contribute to the understanding of the dynamic behavior of heterogeneous layered materials and highlight the potential of interfacial design strategies in enhancing structural performance under extreme conditions.

Topics & Concepts

Materials scienceNeckingComposite materialFracture (geology)SynchrotronComposite numberUltimate tensile strengthDynamic loadingDeformation (meteorology)Tension (geology)Shear (geology)Strain rateSplit-Hopkinson pressure barBridging (networking)Fracture mechanicsCohesive zone modelDeformation mechanismDynamic range compressionTensile testingTensile strainCharacterization (materials science)In situMicrostructure and mechanical propertiesAluminum Alloys Composites PropertiesTitanium Alloys Microstructure and Properties