We present a scheme for calculating the electronic structure of disord
ered alloys, self-consistent in the local-density-approximation sense.
It is based on expanding the one-electron Green's function in the bas
is of modified atomic orbitals [H. Eschrig, Optimized LCAO Method and
the Electronic Structure of Extended Systems (Springer, Berlin, 1989)]
. The two-terminal approximation introduced for the Hamiltonian and th
e overlap matrix permits us to treat both the diagonal and off-diagona
l disorder using an extension of the Blackman-Esterling-Berk form of t
he coherent-potential approximation (CPA) [Phys. Rev. B 4, 2412 (1971)
] to a nonorthogonal basis set. Calculations using the scalar relativi
stic density functional for the magnetic binary transition-metal alloy
s Fe-Co, Fe-Pt, Co-Pt, and for the ternary alloy Al-Fe-Mn give results
comparing well with experimental data and calculations based on the K
orringa-Kohn-Rostoker (KKR)-CPA and linear muffin-tin orbital-CPA tech
niques.