@ mmoderwell

Phase diagram of Fe8BiSb; eabovehull: 0.079838 eV/atom; predicted_stable: False

BiFe8Sb (P4mm) - phonon dispersion

Image

Phonon band structure (supercell [3, 3, 3], Δ=0.01 Å); no imaginary modes; min freq = 0.00 THz

BiFe8Sb (P4mm) - 3x3x3 supercell

Supercell 3x3x3 of Fe8BiSb (Space group: P4mm, 216 symmetry operations)

BiFe8Sb (P4mm)

79 meV above hull

FeCoBi (P3m1)

FeCoBi (space group: P3m1 #156, crystal system: trigonal, point group: 3m)

B4Fe3Ni9 (P1) - 4x4x4 supercell

Supercell 4x4x4 of Fe3Ni9B4 (Space group: P1, 64 symmetry operations)

BiFe6Se3 (P4mm) - 3x3x3 supercell

Supercell 3x3x3 of Fe6BiSe3 (Space group: P4mm, 216 symmetry operations)

Fe6BiSe3 phase diagram

Phase diagram of Fe6BiSe3; eabovehull: 0.186839 eV/atom; predicted_stable: False

BiFe6Se3 (P4mm) - phonon dispersion

Image

Phonon band structure (supercell [3, 3, 3], Δ=0.01 Å); imaginary modes detected; min freq = -0.99 THz

Phase diagram of Zr8Fe2Bi; eabovehull: 0.081061 eV/atom; predicted_stable: False

BiFe2Zr8 (P422) - 3x3x3 supercell

Supercell 3x3x3 of Zr8Fe2Bi (Space group: P422, 216 symmetry operations)

BiFe2Zr8 (P422)

Nb9Co19Bi phase diagram

Phase diagram of Nb9Co19Bi; eabovehull: 0.194784 eV/atom; predicted_stable: False

BiCo19Nb9 (P-6)

Funny, the ones that are most stable have Bi as far as possible from Co/Fe. Not great for SOC!

Nb4Co14Bi phase diagram

Phase diagram of Nb4Co14Bi; eabovehull: 0.277027 eV/atom; predicted_stable: False

BiCo14Nb4 P4/m - 2x2x2 supercell

Supercell 2x2x2 of Nb4Co14Bi (Space group: P4/m, 64 symmetry operations)

BiCo14Nb4 P4/m - phonon dispersion

Image

Phonon band structure (supercell [3, 3, 3], Δ=0.01 Å); imaginary modes detected; min freq = -7.37 THz

BiCo14Nb4 P4/m

high above the hull