Abstract
A systematic study on a face-centered cubic-based compositionally complex alloy system Al-Co-Cr-Cu-Fe-Ni in its single-phase state is carried out, where a mother senary compound Al(8)Co(17)Cr(17)Cu(8)Fe(17)Ni(33) and five of its suballoys, obtained by removing one element at a time, are investigated and exhaustively analyzed determining the contribution of each alloying element in the solid solution. The senary and the quinaries are compared using experimental techniques including X-ray absorption spectroscopy, X-ray diffraction, transmission electron microscopy, and first principles hybrid Monte Carlo/molecular dynamics simulations. Chemical short-range order and bond length distances have been determined both at the experimental and computational level. Electronic structure and local atomic distortions up to 5.2 Å have been correlated to the microhardness values. A linear regression model connecting hardness with local lattice distortions is presented.