THEORETICAL INVESTIGATIONS OF THE ELASTIC-CONSTANTS IN LAVES PHASES

The bulk modulus B and the tetragonal shear modulus C' of the C15 Lave s phases AAl(2), A = Ca, Sc, Y, La and Gd and ZrB2, B = V, Cr, Fe, Co, Zn and Mo; the C14 Laves phases ZrMn2, ZrAl2, ZrCr2, TiCr2, NbCr2 and TaFe2 and the metals forming these Laves phases are studied theoretic ally by ab-initio density functional band structure calculations. Addi tionally, the Poisson ratios, the Young moduli, for cubic systems C-11 and C-12 and for the hexagonal phases C-11 + C-12, C-13 and C-33 are calculated and compared with the experimental data. We also compare th e results of B obtained from the augmented spherical wave method using the local density and atomic sphere approximations and the full poten tial linear muffin-tin orbitals procedure with and without the general ized gradient correction for the crystal potential. All procedures giv e the right trend in B and the differences between experiment and theo ry are less than 15% for systems without a transition element and up t o 25% for systems with a transition metal component. The correlation b etween B and the electron density rho(1) in the interstitial region of the crystal found by Moruzzi et al. for metals can be extended to B f or the Laves phases and allows rules of mixture for B. For C' and the other elastic constants, the agreement between experiment and theory i s similar for the non-transition metals but less satisfactory for the transition metals and the Laves phases with a transition metal compone nt. (C) 1997 Elsevier Science Limited.