Litcius/Paper detail

Evolution of multiscale heterostructures and comprehensive properties improvement in the large thickness ratio Ti/Al/Mg clad plates under heterothermal rolling

Junxin Wei, Jianchao Han, Yi Jia, Tao Wang, Qingxue Huang

2025Journal of Magnesium and Alloys7 citationsDOIOpen Access PDF

Abstract

• Ti/Al/Mg clad plates (1:1:40) fabricated via breakthrough heterothermal rolling. • Peel strength increases 4.2-fold via synergistic temperature-strain gradients. • Multi-scale heterostructure engineered via localized LAGB/CDRX/<c + a> slip regulation. • 301 MPa & 27.8 % elongation synergy from dislocation accumulation and strain hardening. • Stress-mediated twin/slip competition affects CDRX to enhance failure resistance. The preparation process of metal clad plates with large thickness ratios (>20) requires ensuring the substrate thickness while also achieving good mechanical properties, a challenge that traditional rolling processes struggle to meet. In this study, TA1/1060/AZ31 clad plates with large thickness ratios (>40) and engineered heterostructures were fabricated via heterothermal rolling, achieving synergistic enhancements in bonding strength and tensile properties. This is attributed to localized interfacial strain concentration induced by the temperature gradient, and sustained strain hardening within the multiscale heterostructured magnesium matrix. The study reveals that the temperature gradient variation in the normal direction of the matrix causes considerable gradation in its deformation mechanisms and microstructure, resulting in diverse heterostructures. In the hot roller zone, high temperatures and large strains promoted the formation of low-angle grain boundaries (LAGBs) with distinct distribution patterns. In contrast, deformation in the cold roller zone was stress-dominated, where the competition between tensile twins and 〈c+a〉 slip changed at low temperatures. Furthermore, LAGB evolution and 〈c+a〉 slip activity differences caused zone-specific variations in discontinuous dynamic recrystallization (CDRX), affecting dislocation density and grain refinement. The higher CDRX degree in the cold roller zone (soft domain) delayed failure in the hot roller zone (hard domain), while heterogeneities in grain size and texture enhanced strain hardening. The dense presence of 〈c+a〉 dislocations within grains further confirmed the continuous strain hardening behavior. This study provides new insights for the fabrication of metal clad plates with large thickness ratios and the development of novel heterostructures.

Topics & Concepts

Materials scienceSlip (aerodynamics)Composite materialUltimate tensile strengthElongationRecrystallization (geology)Grain sizeGrain boundaryDynamic recrystallizationStrengthening mechanisms of materialsDeformation (meteorology)DislocationTemperature gradientHeterojunctionStrain hardening exponentMicrostructureDeformation mechanismWork hardeningElectron backscatter diffractionLüders bandThermalHardening (computing)PlasticityMetallurgyStrain rateMagnesium alloyMagnesium Alloys: Properties and ApplicationsAluminum Alloys Composites PropertiesAdvanced Welding Techniques Analysis
Evolution of multiscale heterostructures and comprehensive properties improvement in the large thickness ratio Ti/Al/Mg clad plates under heterothermal rolling | Litcius