posted on 2020-01-19, 13:29authored byWilliam C. Jolin, Alissa Richard, Dharni Vasudevan, José A. Gascón, Allison A. MacKay
Current
predictive models of organic cation sorption assume that
sorbates interact with all sites on aluminosilicate minerals in the
same manner. To examine whether differences in aluminosilicate structure
and the resultant changes in electrostatic potential influence the
sorption of organic cations, seven smectites were chosen with different
proportions of isomorphic substitutions (origin of clay charge) located
in octahedral versus tetrahedral layers and with the presence or absence
of aluminosilicate interlayers. Sorption coefficients for 14 benzylamine
derivatives with systematic differences in compound structures were
collected to understand the possible influence of aluminosilicate
mineralogy. Benzylamine compounds with methyl group substitution on
the charged amine or with electron-donating or -withdrawing ring substituents
displayed decreases in cation exchange-normalized sorption coefficients
(KCEC), by up to one order of magnitude,
between hectorite (100% isomorphic substitution in the octahedral
layer) and nontronite (100% isomorphic substitution in the tetrahedral
layer). To understand this difference across aluminosilicates, stochastic
molecular models of the various aluminosilicate minerals with interlayers
were performed. These models showed that negative charge density associated
with tetrahedral sites results in high positive electrostatic energy
barriers within the interlayer, creating a penalty for compounds with
positive charge spread over a larger compound surface area as occurs
from primary to quaternary amines. Conversely, clays with charge originating
from octahedral sites produce low electrostatic potential barriers
within the interlayer, decreasing the penalty for quaternary amine
sorption. Trends for nine cationic pharmaceutical compounds, which
varied in size, group alkylation, and/or polar substituents, demonstrated
similar decreases in KCEC values to aluminosilicate
minerals with high electrostatic energy barriers. Overall, aluminosilicate
mineralogy was found to exert a large influence (0.5–1 order
of magnitude in sorption coefficients) on organic cation sorption.
The application of atomistic electrostatic potential mapping of both
sorbent and sorbate structures provided insights to explain trends
in sorption coefficients that could not be described by the basic
electrostatic potential theory or by assuming that sorbate structure
moieties yielded additive sorption contributions.