Uranium
is an extremely abundant resource in seawater that could
supply nuclear fuel for over the long-term, but it is tremendously
difficult to extract. Here, a new supramolecular poly(amidoxime) (PAO)-loaded
macroporous resin (PLMR) adsorbent has been explored for highly efficient
uranium adsorption. Through simply immersing the macroporous resin
in the PAO solution, PAOs can be firmly loaded on the surface of the
nanopores mainly by hydrophobic interaction, to achieve the as-prepared
PLMR. Unlike existing amidoxime-based adsorbents containing many inner
minimally effective PAOs, almost all the PAOs of PLMR have high uranium
adsorption efficiency because they can form a PAO-layer on the nanopores
with molecular-level thickness and ultrahigh specific surface area.
As a result, this PLMR has highly efficient uranium adsorbing performance.
The uranium adsorption capacity of the PLMR was 157 mg/g (the U
PAO in the PLMR was 1039 mg/g), in 32 ppm uranium-spiked
seawater for 120 h. Additionally, uranium in 1.0 L 100 ppb U-spiked
both water and seawater can be removed quickly and the recovery efficiency
can reach 91.1 ± 1.7% and 86.5 ± 1.9%, respectively, after
being filtered by a column filled with 200 mg PLMR at 300 mL/min for
24 h. More importantly, after filtering 200 T natural seawater with
200 g PLMR for only 10 days, the uranium-uptake amount of the PLMR
reached 2.14 ± 0.21 mg/g, and its average uranium adsorption
speed reached 0.214 mg/(g·day) which is very fast among reported
amidoxime-based adsorbents. This new adsorbent has great potential
to quickly and massively recover uranium from seawater and uranium-containing
wastewater. Most importantly, this work will provide a simple but
general strategy to greatly enhance the uranium adsorption efficiency
of amidoxime-functionalized adsorbents with ultrahigh specific surface
area via supramolecular interaction, and even inspire the exploration
of other adsorbents.
Although
eco-friendly amidoxime-based adsorbents own an excellent
uranium (U)-adsorption capacity, their U-adsorption efficiency is
commonly reduced and even damaged by the biological adhesion from
bacteria/microorganisms in an aqueous environment. Herein, we present
an antibiofouling ultrathin poly(amidoxime) membrane (AUPM) with highly
enhanced U-adsorption performance, through dispersing the quaternized
chitosan (Q-CS) and poly(amidoxime) in a cross-linked sulfonated cellulose
nanocrystals (S-CNC) network. The cross-linked S-CNC not only can
elevate the hydrophilicity to improve the U-adsorption efficiency
of AUPM but also can enhance the mechanical strength to form a self-supporting
ultrathin membrane (17.21 MPa, 10 μm thickness). More importantly,
this AUPM owns a good antibiofouling property, owing to the broad-spectrum
antibacterial quaternary ammonium groups of the Q-CS. As a result,
within the 1.00 L of low-concentration (100 ppb) U-added pure water
(pH ≈ 5) and seawater (pH ≈ 8) for 48 h, 30 mg of AUPM
can recover 93.7% U and 91.4% U, respectively. Furthermore, compared
with the U-absorption capacity of a blank membrane without the Q-CS,
that of AUPM can significantly increase 37.4% reaching from 6.39 to
8.78 mg/g after being in natural seawater for only 25 d. Additionally,
this AUPM can still maintain almost constant tensile strength during
10 cycles of adsorption–desorption, which indicates the relatively
long-term usability of AUPM. This AUPM will be a promising candidate
for highly efficient and large-scale U-recovery from both U-containing
waste freshwater/seawater and natural seawater, which will be greatly
helpful to deal with the U-pollution and enrich U for the consumption
of nuclear power. More importantly, the work will provide a new convenient
but universal strategy to fabricate new highly enhanced low-cost U-adsorbents,
through the introduction of both an antibacterial property and a high
mechanical performance, which will be a good reference for the design
of new highly efficient U-adsorbents.
The extraction of uranium from seawater, which is an abundant resource, has attracted considerable attention as a viable form of energy-resource acquisition. The two critical factors for boosting the chemical thermodynamics of uranium extraction from seawater are the availability of sufficient amounts of uranyl ions for supply to adsorbents and increased interaction temperatures. However, current approaches only rely on the free diffusion of uranyl ions from seawater to the functional groups within adsorbents, which largely limits the uranium extraction capacity. Herein, inspired by the mechanism of plant transpiration, a plant-mimetic directional-channel poly(amidoxime) (DC-PAO) hydrogel is designed to enhance the uranium extraction efficiency via the active pumping of uranyl ions into the adsorbent. Compared with the original PAO hydrogel without plant-mimetic transpiration, the uranium extraction capacity of the DC-PAO hydrogel increases by 79.33% in natural seawater and affords the fastest reported uranium extraction average rate of 0.917 mg g −1 d −1 among the most state-of-the-art amidoxime group-based adsorbents, along with a high adsorption capacity of 6.42 mg g −1 within 7 d. The results indicate that the proposed method can enhance the efficiency of solar-transpiration-based uranium extraction from seawater, particularly in terms of reducing costs and saving processing time.
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