posted on 2023-10-05, 17:34authored byWei Cheng, Jiabin Li, Jie Sun, Tao Luo, Rémi Marsac, Jean-François Boily, Khalil Hanna
Interactions between aqueous Fe(II) and solid Fe(III)
oxy(hydr)oxide
surfaces play determining roles in the fate of organic contaminants
in nature. In this study, the adsorption of nalidixic acid (NA), a
representative redox-inactive quinolone antibiotic, on synthetic goethite
(α-FeOOH) and akaganéite (β-FeOOH) was examined
under varying conditions of pH and cation type and concentration,
by means of adsorption experiments, attenuated total reflectance-Fourier
transform infrared spectroscopy, surface complexation modeling (SCM),
and powder X-ray diffraction. Batch adsorption experiments showed
that Fe(II) had marginal effects on NA adsorption onto akaganéite
but enhanced NA adsorption on goethite. This enhancement is attributed
to the formation of goethite-Fe(II)-NA ternary complexes, without
the need for heterogeneous Fe(II)–Fe(III) electron transfer
at low Fe(II) loadings (2 Fe/nm2), as confirmed by SCM.
However, higher Fe(II) loadings required a goethite–magnetite
composite in the SCM to explain Fe(II)-driven recrystallization and
its impact on NA binding. The use of a surface ternary complex by
SCM was supported further in experiments involving Cu(II), a prevalent
environmental metal incapable of transforming Fe(III) oxy(hydr)oxides,
which was observed to enhance NA loadings on goethite. However, Cu(II)-NA
aqueous complexation and potential Cu(OH)2 precipitates
counteracted the formation of ternary surface complexes, leading to
decreased NA loadings on akaganéite. These results have direct
implications for the fate of organic contaminants, especially those
at oxic–anoxic boundaries.