The binding strength of the carboxylic acid group (-COOH) with different divalent metal ions displays considerable variation in arachidic acid (AA) thin films. It is considered that in AA thin films the metal ions straddle the hydrophilic regions of the stacked bilayers of AA molecules via formation of carboxylates. In this study first the uptake of different divalent cations in films of AA is estimated by atomic absorption spectroscopy (AAS). Through the amount of cation uptake, it is found that the strength of binding of different cations varies as Ca2+>Co2+>Pb2+>Cd2+. Variation in the binding strength of different ions is also manifested in experiments where AA thin films are exposed to metal ion mixtures. The higher binding strength of AA with certain metal ions when exposed individually, as well as the preference over the other metal ions when exposed to mixtures, reveal some interesting deviation from the expected behavior based on considerations of ionic radii. For example, Pb2+ is always found to bind to AA much more strongly than Cd2+ even though the latter has smaller ionic radius, indicating that other factors also play an important role in governing the binding strength trends apart from the effects of ionic radii. Then, to get a more meaningful knowledge regarding the binding capability, first-principles calculations based on density functional theory have been applied to study the interaction of different cations with the simplest carboxylic acid, acetic acid, that can result in formation of metal diacetates. Their electronic and molecular structures, cohesive energies, and stiffness of the local potential energy well at the cation (M) site are determined and attempts are made to understand the diversity in geometry and the properties of binding of different metal ions with -COOH group. We find that the calculated M-O bond energies depend sensitively on the chemistry of M atom and follow the experimentally observed trends quite accurately. The trends in M-O bond energies and hence the total M-acetate binding energy trends can actually be related to their molecular structures that fall into different categories: Ca and Cd have tetrahedral coordination; Fe, Ni, and Co exhibit planar 4-fold coordination; and Pb is off-centered from the planar structure (forming pyramidal structure) due to its stereochemically active lone pair of electrons.
Among the different synthesis approaches
to colloidal nanocrystals,
a recently developed toolkit is represented by cation exchange reactions,
where the use of template nanocrystals gives access to materials that
would be hardly attainable via direct synthesis.
Besides, postsynthetic treatments, such as thermally activated solid-state
reactions, represent a further flourishing route to promote finely
controlled cation exchange. Here, we report that, upon in
situ heating in a transmission electron microscope, Cu2Se or Cu nanocrystals deposited on an amorphous solid substrate
undergo partial loss of Cu atoms, which are then engaged in local
cation exchange reactions with Cu “acceptor” phases
represented by rod- and wire-shaped CdSe nanocrystals. This thermal
treatment slowly transforms the initial CdSe nanocrystals into Cu2–xSe nanocrystals, through the complete
sublimation of Cd and the partial sublimation of Se atoms. Both Cu
“donor” and “acceptor” particles were
not always in direct contact with each other; hence, the gradual transfer
of Cu species from Cu2Se or metallic Cu to CdSe nanocrystals
was mediated by the substrate and depended on the distance between
the donor and acceptor nanostructures. Differently from what happens
in the comparably faster cation exchange reactions performed in liquid
solution, this study shows that slow cation exchange reactions can
be performed at the solid state and helps to shed light on the intermediate
steps involved in such reactions.
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