Gw. Luther et al., DETERMINATION OF METAL (BI)SULFIDE STABILITY-CONSTANTS OF MN2+, FE2+,CO2+, NI2+, CU2+, AND ZN2+ BY VOLTAMMETRIC METHODS, Environmental science & technology, 30(2), 1996, pp. 671-679
The stoichiometry as well as the conditional and thermodynamic stabili
ty constants for the (bi)sulfide complexes of the +2 cations of Mn, Fe
, Ni, Co, Cu, and Zn have been determined by voltammetric methods in s
eawater and chloride solutions of varying ionic strength. Acid-base ti
trations allowed for the determination of the proton stoichiometry of
the complexes. Mn, Fe, Ni, and Co form bisulfide, HS-, complexes of st
oichiometry MSH(+), M(2)(SH)(3+), and M(3)(SH)(5+), which are labile u
nder diffusion control conditions, in seawater at pH values > 7. These
complexes dissociate below pH = 7, releasing H2S from solution. Evide
nce for sulfide-rich complexes of form M(SH)(2) was not found. Cu and
Zn form sulfide, S2-, complexes of stoichiometry MS and M(2)S(3)(2-),
which are inert(nonlabile) under diffusion control conditions, in seaw
ater at pH values > 7. There is no evidence for metal-rich sulfide com
plexes of stoichiometry [M(x)S]2(x-2) from the titration data. The M(2
)S(3)(2-) complexes are tetrameric structures (M(4)S(6)) with tetrahed
ral metal coordination based on known thiolate complex and mineral geo
metries. The Zn complexes dissociate below pH = 6.7, releasing H2S fro
m solution. However, the Cu complex does not fully dissociate below pH
= 2 because of Cu(II) reduction and production of polysulfide, which
do not appear to be quantitative. At seawater pH, both Zn and Cu sulfi
de complexes can be deposited on a mercury drop, indicating that these
metal complexes are likely responsible for the presence of nanomolar
levels of sulfide in oxic seawater.