Phase stability, structural, and electronic properties of iron silicides in
the Fe3Si, FeSi, and FeSi2 compositions are investigated by first-principl
e density-functional calculations based on ultrasoft pseudopotentials and a
ll-electron methods. Structural stabilization versus spin-polarization effe
cts are discussed at the Fe3Si composition, while for epsilon-FeSi and beta
-FeSi2 we investigate their structural properties and the corresponding sem
iconducting band properties. All the computed results are analyzed and comp
ared to available experimental data. The stability of the bulk phases, the
lattice parameters, the cohesive energies and magnetic properties are found
to be in good agreement with experiment when using the generalized gradien
t approximations for the exchange-correlation functional. Density-functiona
l calculations are unable to account for the small bulk modulus of epsilon-
FeSi despite that the computed lattice constant and internal atomic positio
ns coincide with the experimental results. Both full-potential and ultrasof
t-pseudopotential methods confirm for beta-FeSi2 the indirect nature of the
fundamental gap, which is attributed to a transition between Y to 0.6X Lam
bda being 30% smaller than the experimental gap. Ultrasoft pseudopotential
calculations of Fe-Si magnetic phases and of various nonequilibrium metalli
c phases at the FeSi and FeSi2 composition are presented. These calculation
s provide nb initio information concerning the stabilization of metallic ps
eudomorphic phases via high pressures or epitaxy. [S0163-1829(99)05419-3].