Design and fabrication of lightweight AlCrFeNiTi <sub> <i>x</i> </sub> compositionally complex alloys with exceptional specific strength
Jun-Zhi Li, Weizong Bao, Jie Chen, Bohua Yu, Kun Zuo, Tian Gao, Zeyun Cai, Guoqiang Xie
Abstract
Abstract This study focuses on compositionally complex alloys (CCAs), aiming to achieve a balance between high strength and low density for new energy and aerospace applications. The composition of AlCrFeNiTi x CCAs is strategically guided by employing density functional theory and the theoretical design of thermodynamic calculations. Bulk CCAs, particularly AlCrFeNiTi 0.25 alloy, demonstrate remarkable specific yield strength (1640.8 MPa) and 22.7% maximum strain. The incorporation of Ti facilitates the formation of lightweight and high‐strength L2 1 phase, contributing to the overall high specific strength. Synergistic effects of grain boundary strengthening, solid solution strengthening, Orowan strengthening and Peierls flow stress further enhance strength. Detailed exploration of microstructural changes during fracture reveals the role of ordered phases in suppressing crack propagation and absorbing energy within disordered phases, thereby improving the toughness and fracture resistance of CCAs. These methods and discoveries establish a robust foundation for advancing the development of novel lightweight CCAs.