Sulfur K‐edge x‐ray absorption near‐edge structure spectroscopy (XANES) was used to identify multiple organic S oxidation states in aquatic and soil humic substances. The XANES results suggest that S in humic substances exists in four major oxidation groups similar to sulfate ester, sulfonate, sulfoxide, and thiol‐sulfide. Thiol S cannot be separated from sulfide S and must be considered as a single thiol‐sulfide peak. The second derivative spectra suggest the existence of thiophene and sulfone S. The relative quantities of each major S form in our humic samples were estimated based on the integrated cross section of each s → p transition peak corresponding to different S oxidation states in the S K‐edge XANES spectra. The XANES results of the four humic samples used in this study appear to reflect the environmental settings where the humic substances originally formed. The percentage of the most reduced organic S (thiol‐sulfide and possibly thiophene) in humic substances follows the sequence: aquatic samples > organic soil sample > mineral soil sample. The percentage of most oxidized S (sulfate group) was the greatest in the humic substance from a mineral soil and the lowest in the aquatic humic substances.
Analysis of Hg(II) complexed by a soil humic acid (HA)
using synchrotron-based X-ray absorption spectroscopy
(XAS) revealed the importance of reduced sulfur functional
groups (thiol (R−SH) and disulfide (R−SS−R)/disulfane (R−SSH)) in humic substances in the complexation of Hg(II). A two-coordinate binding environment with one oxygen
atom and one sulfur atom at distances of 2.02 and 2.38
Å, respectively, was found in the first coordination shell
of Hg(II) complexed by humic acid. Model calculations show
that a second coordination sphere could contain one
carbon atom and a second sulfur atom at 2.78 and 2.93
Å, respectively. This suggests that in addition to thiol S,
disulfide/disulfane S may be involved with the complexation
of Hg(II) in soil organic matter. The appearance of
carbon atom in the second coordination shell suggests
that one O-containing ligand such as carboxyl and phenol
ligands rather than H2O molecule is bound to the Hg(II).
The involvement of oxygen ligand in addition to the reduced
S ligands in the complexation of Hg(II) is due to the low
density of reduced S ligands in humic substances. The XAS
results from this experiment provided direct molecular
level evidence for the preference of reduced S functional
groups over oxygen ligands by Hg(II) in the complexation
with humic substances.
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