First principles calculations of the electronic and geometric structure of Ag27Cu7 nanoalloy

Abstract

Ab initio calculations of the structure and electronic density of states (DOS) of the perfect core-shell Ag27Cu7 nanoalloy attest to its D5h symmetry and confirm that it has only 6 non-equivalent (2 Cu and 4 Ag) atoms. Analysis of bond-length, average formation energy, heat of formation of Ag27Cu7 and L12 Ag-Cu alloys provide an explanation for the relative stability of the former with respect to the other nanoalloys in the same family. The HOMO-LUMO gap is found to be 0.77 eV, in agreement with previous results. Analysis of the DOS of Ag27Cu7, L12 Ag-Cu alloys and related systems provides insight into the effects of low coordination, contraction/expansion and the presence of foreign atoms on the DOS of Cu and Ag. While some characteristics of the DOS are reminiscent of those of the phonon-stable L12 Ag-Cu alloys, the Cu and Ag states hybridize significantly in Ag27Cu7, compensating the d-band narrowing that each atom undergoes and hindering the dip in the DOS found in the bulk alloys. Charge density plots of Ag27Cu7 provide further insights into the relative strengths of the various interatomic bonds. Our results for the electronic and geometric structure of this nanoalloy can be explained in terms of length and strength hierarchies of the bonds, which may have implications also for the stability of alloy in any phase or size.