Gold at ∼20 °C with F2 in anhydrous hydrogen
fluoride (aHF) acidified with SbF5 dissolves to a
red
solution from which orange
AuII(SbF6)2 crystallizes on
removal of volatiles. Au(SbF6)2 is
triclinic with a = 5.300(1)
Å, b = 5.438(1) Å, c = 8.768(2)
Å, α = 76.872(3)°, β = 88.736(3)°, γ =
68.109(3)°, V = 227.79(7) Å3, and
Z =
1, space group P1̄. Each Au(II) atom, at
1̄, is at the center of an elongated octahedron of F ligands; the
four F's of
the approximately square AuF4 unit are at 2.09(2) Å
× 2 Å and 2.15(2) Å × 2, each F provided by a different
SbF6
species. The two long Au−F interatomic distances are at
2.64(2) Å. The SbF6 are grossly distorted in
their interactions
with the Au. A cis pair of F ligands of each
SbF6, make close approach to two different gold atoms,
stretching
Sb−F to 1.99(2) and 1.94(2) Å. In each case the
Sb−F distances trans to these stretched Sb−F bonds are
short,
being 1.85(2) and 1.84(2) Å, respectively. Magnetic
susceptibility measurements show antiferromagnetic
coupling
with a susceptibility decrease below 13 K. Solvolysis of
AuII(SbF6)2 in aHF is
accompanied by disproportionation:
4Au(SbF6)2 → Au +
Au3F8 + 8SbF5(solv).
Fluorination, at ∼20 °C, of the solution of
Au(SbF6)2, in SbF5
acidified
aHF, precipitates red crystals of triclinic
AuII{SbF6}2AuII{AuIIIF4}2
with a
o = 5.2345(2) Å,
b
o = 8.1218(1) Å,
c
o =
10.5977(3) Å, α = 100.090(2)°, β =
100.327(2)°, γ = 104.877(2)°, V =
416.63(2) Å3, space group P1̄, and
Z = 1.
It is a simple paramagnet. The structure shows two different
Au(II) environments, each approximately square-coordinated by F ligands, one being coordinated trans by an F
ligand of each of two SbF6 and similarly by an
F
ligand from each of two AuIIIF4 species.
The other Au(II) is approximately square-coordinated via
bridging F ligands
to four different AuIIIF4 species.
AuII{SbF6}2AuII{AuIIIF4}2
with KAuF4 in aHF yields Au3F8 free
of metallic gold,
the simple paramagnetism of which indicates the formulation
AuII{AuIIIF4}2.
