On the inhomogeneous deformation behavior of magnesium alloy beam subjected to bending

Magnesium (Mg) alloys have attracted worldwide attention as potential lightweight structural materials. However, it is still a big challenge to manufacture or process Mg alloys that have good formability and endure high strength. This mainly stems from the lack of understanding the anisotropic mechanical behavior of Mg alloys subjected to inhomogeneous deformation which exists inevitably in various material processing routes. In this respect, the current work seeks to explore and understand the bending behavior of Mg alloy. Mechanical response and microstructure development were experimentally characterized by performing four-point bending tests, with the use of the in-situ digital-image-correlation (DIC) and ex-situ electro backscattered diffraction (EBSD) measurements. Meanwhile, a crystal plasticity-based approach was proposed and used to illustrate the characteristic deformation behavior under four-point bending. The inhomogeneous and anisotropic nature of the mechanical response of Mg alloys under bending is successfully captured by the proposed approach in terms of the moment-curvature relation, the deformed cross-sectional shape of the beam, the developed textures at different regions of the beam, the spatial distribution of the stress and strain components, and the twin volume fraction. The insight of the slip/twinning mechanisms underlying the bending behavior of Mg alloy beam offers a novel way for designing/tuning gradient twinning structures that might lead to the optimized properties of Mg alloys.

Automated summary

This study investigates the bending behavior of magnesium (Mg) alloys through four-point bending tests and various measurement techniques. The research reveals the inhomogeneous and anisotropic mechanical response of Mg alloys under bending, and proposes a crystal plasticity-based approach to describe their deformation behavior. The insights from this study offer new possibilities for designing and controlling gradient twinning structures to optimize the properties of Mg alloys.