posted on 2020-11-17, 02:29authored byMohamed
H. Hassan, Robert Stanton, Jeremy Secora, Dhara J. Trivedi, Silvana Andreescu
Phosphate removal has become a critical
need to mitigate the negative
effect of water eutrophication, which is responsible for the overgrowth
of toxic algal blooms and the significant ecological harm generated
to aquatic ecosystems. However, some of the currently available adsorbents
have low removal capacity and function optimally at specific pH ranges.
Here, we present an example of a cerium-based metal–organic
framework (MOF) as a high-capacity sorbent for phosphate removal from
eutrophic waters. Specifically, a Ce(IV)-based UiO-66 analogue, Ce
1,4-benzenedicarboxylate (Ce-BDC), was selected due to its water stability,
high surface area, microporous structure, and the high binding affinity
of phosphate with its open metal sites. Mechanistic studies supported
by density functional theory (DFT) calculations indicate the formation
of a Ce–O–P bond through ion exchange between the terminal
(nonbridging) hydroxyl groups at the missing linker sites and the
phosphate adducts. Experimental results demonstrate that Ce-BDC is
highly selective for phosphates over other common anions (Cl–, Br–, I–, NO3–, HCO3–, SO42–) and stable in a broad
pH range of (2–12), covering the relevant range for the treatment
of contaminants in aquatic systems. The sorbent shows a fast removal
rate, capturing significant amounts of phosphate within 4 min with
a maximum adsorption capacity of 179 mg·g–1, outperforming other porous materials. These results show a remarkable
adsorption capacity and fast kinetics compared with the current state-of-the-art
crystalline porous materials. This study may advance the design of
new microporous materials with high adsorption capabilities, good
stability, and make a significant contribution to the development
of future generation technology to mitigate the negative effects of
water eutrophication.