Phosphate
is an important anion in both the aquatic environment
and biological systems. The search for a selective and sensitive phosphate
ratiometric fluorescent probe to quantify the phosphate level in water
samples and body fluids is of great significance for the protection
of the ecological environment and human health. Here, a porphyrin-based
nano metal–organic framework (NMOF), PCN-224, was successfully
exploited as a simple but highly sensitive and selective single-component
ratiometric fluorescent probe with accurate composition and measurable
structure for the quantitative determination of phosphate, based on
the interesting double-emission fluorescence of the porphyrin ligand
itself. Compared with other zirconium-based NMOF probes for phosphate,
the reduced number of connections for ZrO clusters with the ligand
in PCN-224 obtained by a linker-elimination strategy simultaneously
provides more active recognition sites for phosphate, which effectively
improves the sensitivity of the zirconium-based NMOF probes. The detection
limit of the probe is only 54 nM. Additionally, the accuracy of the
ratiometric detection based on this probe was further proved by the
detection of phosphate in human serum and drinking water.
With graphene-like topology and designable functional moieties, single-layered covalent organic frameworks (sCOFs) have attracted enormous interest for both fundamental research and application prospects. As the growth of sCOFs involves the assembly and reaction of precursors in a spatial defined manner, it is of great importance to understand the kinetics of sCOFs formation. Although several large families of sCOFs and bulk COF materials based on different coupling reactions have been reported, the synthesis of isomeric sCOFs by exchanging the coupling reaction moieties on precursors has been barely explored. Herein, a series of isomeric sCOFs based on Schiff-base reaction is designed to understand the effect of monomer structure on the growth kinetics of sCOFs. The distinctly different local packing motifs in the mixed assemblies for the two isomeric routes closely resemble to those in the assemblies of monomers, which affect the structural evolution process for highly ordered imine-linked sCOFs. In addition, surface diffusion of monomers and the molecule-substrate interaction, which is tunable by reaction temperature, also play an important role in structural evolutions. This study highlights the important roles of monomer structure and reaction temperature in the design and synthesis of covalent bond connected functional nanoporous networks.
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