posted on 2017-04-18, 00:00authored byBin Ma, Alejandro Fernandez-Martinez, Sylvain Grangeon, Christophe Tournassat, Nathaniel Findling, Francis Claret, Ayumi Koishi, Nicolas C. M. Marty, Delphine Tisserand, Sarah Bureau, Eduardo Salas-Colera, Erik Elkaïm, Carlo Marini, Laurent Charlet
Layered
double hydroxides (LDHs) have been considered as effective
phases for the remediation of aquatic environments, to remove anionic
contaminants mainly through anion exchange mechanisms. Here, a combination
of batch isotherm experiments and X-ray techniques was used to examine
molybdate (MoO42–) sorption mechanisms
on CaAl LDHs with increasing loadings of molybdate. Advanced modeling
of aqueous data shows that the sorption isotherm can be interpreted
by three retention mechanisms, including two types of edge sites complexes,
interlayer anion exchange, and CaMoO4 precipitation. Meanwhile,
Mo geometry evolves from tetrahedral to octahedral on the edge, and
back to tetrahedral coordination at higher Mo loadings, indicated
by Mo K-edge X-ray absorption spectra. Moreover, an anion exchange
process on both CaAl LDHs was followed by in situ time-resolved synchrotron-based
X-ray diffraction, remarkably agreeing with the sorption isotherm.
This detailed molecular view shows that different uptake mechanismsedge
sorption, interfacial dissolution-reprecipitationare at play
and control anion uptake under environmentally relevant conditions,
which is contrast to the classical view of anion exchange as the primary
retention mechanism. This work puts all these mechanisms in perspective,
offering a new insight into the complex interplay of anion uptake
mechanisms by LDH phases, by using changes in Mo geometry as powerful
molecular-scale probe.