Selective extraction of uranium from water has attracted worldwide attention because the largest source of uranium is seawater with various interference ions (Na , K , Mg , Ca , etc.). However, traditional adsorbents encapsulate most of their functional sites in their dense structure, leading to problems with low selectivity and adsorption capacities. In this work, the tailor-made binding sites are first decorated into porous skeletons, and a series of molecularly imprinted porous aromatic frameworks are prepared for uranium extraction. Because the porous architecture provides numerous accessible sites, the resultant material has a fourfold increased ion capacity compared with traditional molecularly imprinted polymers and presents the highest selectivity among all reported uranium adsorbents. Moreover, the porous framework can be dispersed into commercial polymers to form composite components for the practical extraction of uranium ions from simulated seawater.
Artificially designed enzymes are in demand as ideal catalysts for industrial production but their dense structure conceals most of their functional fragments, thus detracting from performance. Here, molecularly imprinted porous aromatic frameworks (MIPAFs) which are exploited to incorporate full host-guest interactions of porous materials within the artificial enzymes are presented. By decorating a porous skeleton with molecularly imprinted complexes, it is demonstrated that MIPAFs are porous artificial enzymes possessing excellent kinetics for guest molecules. In addition, due to the abundance of accessible sites, MIPAFs can perform a wide range of sequential processes such as substrate hydrolysis and product transport. Through its two functional sites in tandem, the MIPAF subsequently manifests both hydrolysis and transport behaviors. Advantageously, the obtained catalytic rate is ≈58 times higher than that of all other conventional artificial enzymes and even surpasses by 14 times the rate for natural organophosphorus hydrolase (Flavobacterium sp. strain ATCC 27551).
Facile
construction of ordered macroporous polyoxometalate-based
metal–organic frameworks (POM@MOFs) to break the intrinsic
microporous restriction is significant but remains challenging. On
one hand, the POMs introduced improve the structural stability and
modify the pores of MOFs, e.g., introducing functional
catalytic and adsorptive units. Meanwhile, the acidic POMs severely
affect the nucleation and growth of the POM@MOFs, resulting in complicated
synthesis and difficult assembly control. Herein, a general approach
has been developed to fabricate ordered macroporous POM@MOF single
crystals, involving close-packed polystyrene (PS) nanosphere templates.
The artificially selected polar solvents exerting strong solvent effect
with POMs weaken the affinity between POMs and metal ions, thereby
effectively stabilizing the precursors from assembly before filling
into the PS template interstices. The weak alkaline carboxylate used
regulates the in situ nucleation and growth of POM@MOFs
through deprotonation of the ligands as well as coordinating modulation,
affording a series of hierarchically cuboctahedral POM@MOF single
crystals with ordered macropores (ca. 180 nm) and
intrinsic micropores after template removal. The ordered macroporous
structure and thinned microporous skeleton markedly improve mass diffusion
properties, while the integral single-crystal lattice retains superior
stability.
High-speed capturing of uranyl (UO 2 2+ ) ions from seawater elicits unprecedented interest for the sustainable development of the nuclear energy industry. However, the ultralow concentration (∼3.3 μg L −1 ) of uranium element leads to the slow ion diffusion inside the adsorbent particle, especially after the transfer paths are occupied by the coexisted interfering ions. Considering the geometric dimension of UO 2 2+ ion (a maximum length of 6.04−6.84 Å), the interlayer spacing of graphene sheets was covalently pillared with phenyl-based units into twice the ionic length (13 Å) to obtain uranyl-specific nanofluidic channels. Applying a negative potential (−1.3 V), such a charge-governed region facilitates a unipolar ionic transport, where cations are greatly accelerated and co-ions are repelled. Notably, the resulting adsorbent gives the highest adsorption velocity among all reported materials. The adsorption capacity measured after 56 days of exposure in natural seawater is evaluated to be ∼16 mg g −1 . This novel concept with rapid adsorption, high capacity, and facile operating process shows great promise to implement in real-world uranium extraction.
Mechanically interlocked
molecules (MIMs) with discrete molecular
components linked through a mechanical bond in space can be harnessed
for the operation of molecular switches and machines, which shows
huge potential to imitate the dynamic response of natural enzymes.
In this work, rotaxane compounds were adopted as building monomers
for the synthesis of a crown-ether ring mechanically intercalated
covalence organic framework (COF). This incorporation of MIMs into
open architecture implemented large amplitude motions, whose wheel
slid along the axle in response to external stimulation. After impregnation
with Zn
2+
ions, the relative locations of two zinc active
sites (crown-ether coordinated Zn(II) and bipyridine coordinated Zn(II))
are endowed with great flexibility to fit the conformational transformation
of an organophosphorus agent during the hydrolytic process. Notably,
the resulting self-adaptive binuclear zinc center in a crown-ether-threaded
COF network is endowed with a record catalytic ability, with a rate
over 85.5 μM min
–1
for organophosphorus degradation.
The strategy of synthesis for porous artificial enzymes through the
introduction of mechanically bound crown ether will enable significant
breakthroughs and new synthetic concepts for the development of advanced
biomimetic catalysts.
Lithium (Li) extraction from brines is a major barrier to the sustainable development of batteries and alloys; however, current separation technology suffers from a trade-off between ion selectivity and permeability. Herein, a crown ether mechanically interlocked 3D porous organic framework (Crown-POF) was prepared as the porous filler of thin-film nanocomposite membranes. Crown-POF with penta-coordinated (four O crown atoms and one N tert-amine atom) adsorption sites enables a special recognition for Li + ion. Moreover, the four N tertamine atoms on each POF branch facilitate the flipping motion of Li + ion along the skeletal thread, while retaining the specified binding pattern. Accordingly, the crown ether interlocked POF network displays an ultrafast ion transfer rate, over 10 times that of the conventional porous materials. Notably, the nanocomposite membrane gives high speed and selectivity for Li + ion transport as compared with other porous solid-based mixed-matrix membranes.
Despite the remarkable mechanical/optical/electrical properties, the inorganic particles and dynamic polymer assemblies encountered the difficulties in compatibility with structural order and complexity. Here, covalent organic frameworks (COFs) constructed through reversible...
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