Litcius/Paper detail

Enhanced strength-ductility synergy in an Al–Cu alloy via Cd-induced hybrid θ″+θ′ precipitation

Hongwei Bai, Xiang Xia Wu, Wei Zhao, Binghan Huangfu, Shengxian Cheng, Zhaoyang Wu, Yujing Liu, Yihan Gao, X.C. Liu

2024Journal of Materials Research and Technology23 citationsDOIOpen Access PDF

Abstract

In this work, trace Cd addition (∼0.2 wt%) was exploited in Al–Cu alloys to improve the mechanical properties by introducing the hybrid θ″+θ′ precipitates, as governed by the solid-solution temperature T. In detail, if the solid solution temperature is low (T = 500 °C), Cd microalloying merely initiates undesirable dual precipitates of θ″ and θ′ precipitates with similar size and homogenous distribution. In such case, the Cd-microalloyed Al–Cu alloy suffers from limited optimization on the strength-ductility synergy in comparison to the Cd-free Al–Cu alloy. However, elevating T to 530 °C results in the formation of dense Cd-rich nanoparticles, significantly promoting the hybrid θ″+θ′ precipitation with bimodal distribution by offering numerous heterogeneous Cd-rich nucleation sites. Such hybrid θ″+θ′ precipitation imparts the architecture of microstructural heterogeneity, which was found to be responsible for the rapid age-hardening response and enhanced strength-ductility synergy in the Cd-microalloyed Al–Cu alloy.

Topics & Concepts

Materials scienceAlloyPrecipitationNucleationDuctility (Earth science)Precipitation hardeningMetallurgyStrengthening mechanisms of materialsChemical engineeringThermodynamicsEngineeringMeteorologyCreepPhysicsAluminum Alloy Microstructure PropertiesAluminum Alloys Composites PropertiesMicrostructure and mechanical properties