posted on 2014-09-11, 00:00authored byWei Bu, Hao Yu, Guangming Luo, Mrinal K. Bera, Binyang Hou, Adam W. Schuman, Binhua Lin, Mati Meron, Ivan Kuzmenko, Mark
R. Antonio, L. Soderholm, Mark L. Schlossman
Selective extraction of metal ions
from a complex aqueous mixture
into an organic phase is used to separate toxic or radioactive metals
from polluted environments and nuclear waste, as well as to produce
industrially relevant metals, such as rare earth ions. Selectivity
arises from the choice of an extractant amphiphile, dissolved in the
organic phase, which interacts preferentially with the target metal
ion. The extractant-mediated process of ion transport from an aqueous
to an organic phase takes place at the aqueous–organic interface;
nevertheless, little is known about the molecular mechanism of this
process despite its importance. Although state-of-the-art X-ray scattering
is uniquely capable of probing molecular ordering at a liquid–liquid
interface with subnanometer spatial resolution, utilizing this capability
to investigate interfacial dynamical processes of short temporal duration
remains a challenge. We show that a temperature-driven adsorption
transition can be used to turn the extraction on and off by controlling
adsorption and desorption of extractants at the oil–water interface.
Lowering the temperature through this transition immobilizes a supramolecular
ion–extractant complex at the interface during the extraction
of rare earth erbium ions. Under the conditions of these experiments,
the ion–extractant complexes condense into a two-dimensional
inverted bilayer, which is characterized on the molecular scale with
synchrotron X-ray reflectivity and fluorescence measurements. Raising
the temperature above the transition leads to Er ion extraction as
a result of desorption of ion–extractant complexes from the
interface into the bulk organic phase. XAFS measurements of the ion–extractant
complexes in the bulk organic phase demonstrate that they are similar
to the interfacial complexes.