We use density functional theory to calculate the electronic band structures,
cohesive energies, phonon dispersions, and optical absorption spectra of
two-dimensional In2βX2β crystals, where X is S, Se, or Te. We identify two
crystalline phases (alpha and beta) of monolayers of hexagonal In2βX2β, and
show that they are characterized by different sets of Raman-active phonon
modes. We find that these materials are indirect-band-gap semiconductors with a
sombrero-shaped dispersion of holes near the valence-band edge. The latter
feature results in a Lifshitz transition (a change in the Fermi-surface
topology of hole-doped In2βX2β) at hole concentrations nSβ=6.86Γ1013 cmβ2, nSeβ=6.20Γ1013 cmβ2,
and nTeβ=2.86Γ1013 cmβ2 for X=S, Se, and Te,
respectively, for alpha-In2βX2β and nSβ=8.32Γ1013
cmβ2, nSeβ=6.00Γ1013 cmβ2, and nTeβ=8.14Γ1013 cmβ2 for beta-In2βX2β.Comment: 9 pages. arXiv admin note: text overlap with arXiv:1302.606