Creation of Cationic Polymeric Nanotrap Featuring High Anion Density and Exceptional Alkaline Stability for Highly Efficient Pertechnetate Removal from Nuclear Waste Streams

There is an urgent need for highly efficient sorbents capable of selectively removing 99TcO4– from concentrated alkaline nuclear wastes, which has long been a significant challenge. In this study, we present the design and synthesis of a high-performance adsorbent, CPN-3 (CPN denotes cationic polymeric nanotrap), which achieves excellent 99TcO4– capture under strong alkaline conditions by incorporating branched alkyl chains on the N3 position of imidazolium units and optimizing the framework anion density within the pores of a cationic polymeric nanotrap. CPN-3 features exceptional stability in harsh alkaline and radioactive environments as well as exhibits fast kinetics, high adsorption capacity, and outstanding selectivity with full reusability and great potential for the cost-effective removal of 99TcO4–/ReO4– from contaminated water. Notably, CPN-3 marks a record-high adsorption capacity of 1052 mg/g for ReO4– after treatment with 1 M NaOH aqueous solutions for 24 h and demonstrates a rapid removal rate for 99TcO4– from simulated Hanford and Savannah River Site waste streams. The mechanisms for the superior alkaline stability and 99TcO4– capture performances of CPN-3 are investigated through combined experimental and computational studies. This work suggests an alternative perspective for designing functional materials to address nuclear waste management.


■ INTRODUCTION
Nuclear energy, a sustainable and ecofriendly power source, has a low fuel utilization rate of only 0.6%. 1 To improve this, countries are actively exploring reprocessing spent nuclear fuel as a promising solution. 2However, the conventional method, plutonium uranium reduction extraction (PUREX), faces challenges like high costs and equipment corrosion. 3Urgent investigation of cost-effective and environmentally benign alternatives, such as carbonate extraction (CARBEX), is crucial.CARBEX effectively separates fission products, providing a viable solution for managing alkaline high-level radioactive waste without PUREX's limitations. 4−7 An essential challenge lies in the efficient separation of fission products under highly alkaline conditions.Notably, technetium-99 ( 99 Tc) emerges as a significant fission product abundantly present in alkaline waste.In aqueous solutions, 99 Tc is primarily found as the pertechnetate anion ( 99 TcO 4 − ), which has high water solubility, toxicity, and environmental mobility, leading to its depth removal by the traditional precipitation method difficult. 8,9Consequently, a primary research focus is the development of a selective removal technique targeting 99 TcO 4 − in alkaline waste.Ion exchange is considered one of the most promising technologies for selectively capturing and separating 99 TcO 4 − due to its high efficiency and ease of operation.Various ionexchange materials have been tested for 99 TcO 4 − removal. 8ationic inorganic materials, such as layered double hydroxides (LDHs), 10 framework hydroxide, 11 and thorium borate, 12,13 are advantageous in terms of easy preparation and low cost, but their low capture capacity and poor selectivity toward 99 TcO 4 − hinder their practical application in alkaline nuclear waste streams.Commercially available organic anion-exchange resins such as Puroilte A530E and A532E exhibit good sorption selectivity toward 99 TcO 4 − ; however, slow sorption kinetics and poor radiation resistance are inevitable issues. 14ationic organic−inorganic hybrid materials, such as metal− organic frameworks (MOFs), exhibit a high adsorption capacity, fast sorption kinetics, and high selectivity toward 99 TcO 4 − .−19 Additionally, the high cost of MOFs presents a barrier to their practical application.Therefore, there is a crucial need for the development of highly efficient, alkaline-stable, and cost-effective sorbents for 99 TcO 4 − removal from alkaline nuclear wastes.Another factor that needs to be noted is that the concentration of anions in the adsorbent directly affects the sorption performance for 99 TcO 4 − when the ion-exchange method was used.To increase the anion capacity in framework materials, modifications can be made by reducing the size of noncharged fragments in the repeating units while preserving the charged fragments and increasing the number of charged fragments in the repeating units.
Cationic polymeric nanotraps (CPNs), a subclass of porous organic polymers (POPs), are constructed by utilizing cationic organic building blocks through covalent bonds or postsynthesis functionalization of a neutral POP material with cationic groups.−35 The CPNs constructed from imidazoliumbased organic building units show excellent selective adsorption performance toward 99 TcO 4 − /ReO 4 − . 26,28,35,36owever, imidazolium moieties are inherently unstable in highly alkaline conditions.−41 This drawback directly affects the adsorption of 99 TcO 4 − /ReO 4 − by imidazolium-based CPNs under alkaline conditions.For example, two such adsorbents reported by us, SCU-CPN-1 and SCU-CPN-2, exhibited a significant decrease in adsorption capacity for ReO 4 − after immersion in a NaOH solution, indicating their structural instability in highly alkaline environments. 42−40 We incorporated this strategy into the construction of imidazolium-based adsorbents and successfully obtained an adsorbent named SCU-CPN-4 with excellent alkaline stability for 99 TcO 4 − /ReO 4 − .However, while this modification increases material stability, it significantly reduces the concentration of the anion in the material, resulting in a low ReO 4 − adsorption capacity of 437 mg/g. 42It is reported that introducing branched alkyl groups (e.g., isopropyl) solely at the N3 position of the imidazolium ion can greatly enhance the alkaline stability of the resulting materials. 39Moreover, N3-substituted imidazolium cations can be synthesized in a one-step process through simple nucleophilic substitution reactions, offering better economic feasibility.Bearing this in mind, we present a strategy for constructing highly alkaline-stable imidazolium-based adsorbents for efficient capture of 99 TcO 4 − /ReO 4 − under strong alkaline conditions (Figure 1).
This strategy involves introducing branched alkyl chains on the N3 of imidazolium units and increasing the density of counteranions within the pores of CPNs.The introduction of alkyl chains protects the imidazolium units from attack by OH − groups, while the high anion density ensures a high adsorption capacity for 99 S1).Nonetheless, this correlation has long been disregarded in the development of high-performance 99 TcO 4 − /ReO 4 − sorbents.On the other hand, the introduction of branched alkyl groups at the N3 position is an effective strategy for preventing the degradation of imidazolium units under alkaline conditions.Taking these considerations into account, our initial approach involves regulating the anion density of the monomers through a quaternization reaction between 1vinyl-1H-imidazole and a benzene ring with different benzyl bromide substituents and named M-1, M-2, and M-3, respectively (Figures S1−3).The successful synthesis of these monomers was confirmed through proton nuclear magnetic resonance ( 1 H NMR) spectroscopy (Figure S1−3) analyses.Subsequently, the monomers were polymerized in the presence of azobis(isobutyronitrile) (AIBN) in dimethylfor-mamide (DMF) aqueous solution at 100 °C.Following ion exchange with Cl − in NaCl aqueous solutions, the polymers were obtained in quantitative yield, denoted as CPN-1, CPN-2, and CPN-3, respectively (Figures 2a, S4). 43,44Theoretical Cl − densities in CPN-1, CPN-2, and CPN-3 were calculated to be 5.50, 5.93, and 6.17 mmol/g, respectively.These values are comparable to or higher than those of other benchmark 99 TcO 4 − sorbents, suggesting the potential applications of these materials in the adsorptive removal of 99 TcO 4 − through ion-exchange processes (Figure S5, Table S1).The Fourier transform infrared (FT-IR) spectra of CPN-1, CPN-2, and CPN-3, along with their corresponding monomers, are presented in Figures S7− 9.In the monomers, the identification of a carbon−carbon double bond through stretching mode ν(C=C) is obscured by the occurrence of phenyl and azole ring stretching vibrations in the same region.However, the presence of the alkene group is best characterized by the CH deformation modes (δ), which are manifested as strong  absorption features in the range of 900−950 cm −1 . 45The absence of these δ(=CH, =CH 2 ) bands upon formation of the polymers indicates the completion of the polymerization reaction of the monomers (Figures S7−9).Figure 2b shows the solid-state 13 C cross-polarization with magic-angle spinning (CP-MAS) NMR spectra, which identifies a new broad resonance at around 40.0 ppm for all three CPNs, confirming the presence of alkyl carbon atoms and further indicating the successful construction of the polymer.The complete anion exchange, substituting Br − with Cl − , was confirmed through energy dispersive X-ray spectroscopy (EDS) analysis, as evidenced by the invisible Br signals in the EDS spectrum (Figures S10−12).Scanning electron microscopy (SEM) revealed similar morphologies for all three CPNs (Figure 2c).Alkaline Stability.We then conducted a systematic investigation into the alkaline stability of the three CPNs while also assessing the alkaline stability of their corresponding monomers for comparative purposes.Since the monomers are soluble in water, 1 H NMR was used to characterize their alkaline stability.We noticed a significant decrease in the intensity of the H atoms associated with the C4 and C5 positions of the imidazolium unit in the M-1 monomer after only 5 min of exposure to 1 M NaOH D 2 O solutions.After 60 min, these H atoms completely vanished, while a new peak emerged at around 7.3 ppm.Additionally, 3 days later, we observed the formation of insoluble solid material in the NMR tube (Figure S14).−40 With an increase in the number of imidazolium units, we observed an accelerated rate of degradation.Specifically, in the case of M-3, degradation was particularly pronounced.After just 5 min of contact with 1 M NaOH D 2 O solutions, the signals corresponding to the H atoms of M-3 completely disappeared, indicating its remarkably diminished stability under alkaline conditions (Figure S16).With the help of attenuated total reflection (ATR) technology, we were able to obtain the IR spectra of the three monomers before and after treatment with NaOH aqueous solution.Figure S17 shows that after soaking in 1 M NaOH aqueous solution for 60 min, there is a significant decrease in the intensity of the ν(CH) Ph and δ(CH) peaks for M-1.These peaks completely disappear when the NaOH aqueous solution concentration reaches 5 M. The other two monomers also exhibit similar changes in their spectra.These observations further confirm the instability of the three monomers in NaOH aqueous solution, which is consistent with the analysis of the 1 H NMR data.The alkaline stability of the CPNs was investigated using FT-IR spectroscopy due to their insolubility in water.Figure 2d demonstrates that even after exposure to 5 M NaOH aqueous solutions for 24 h, the FT-IR spectra of CPN-1, CPN-2, and CPN-3 remained almost identical compared to the pristine samples, indicating their exceptional stability when subjected to strong alkaline conditions.Furthermore, SEM images of the three samples after being immersed in 1, 3, and 5 M NaOH aqueous solutions show that their morphology remains unchanged, with no noticeable erosion marks observed on the surface (Figure S18).This further confirms their exceptional stability in alkaline solutions.The remarkable stability of the three CPNs can be attributed to the following reasons.First, the polymeric network of the CPNs is insoluble in water, which limits the contact between the imidazolium units and the OH − ions compared to the soluble monomers.Second, the alkyl chains formed through the free-radical polymerization of olefinic bonds play a crucial role in further safeguarding the imidazolium units from attack by OH − ions by providing local hydrophobic environments.The combination of these two factors synergistically contributes to the exceptional stability of the three materials.The cationic framework with high anion density, combined with the remarkable resistance to alkaline conditions exhibited by the CPNs, encourages further investigation into their potential for effectively removing 99 TcO 4 − from HLW streams.Sorption Isotherm Analysis.Considering that sorption capacity is predominantly influenced by anion density, we conducted tests to evaluate the sorption capacities of these materials toward ReO 4 − .ReO 4 − serves as an ideal nonradioactive surrogate for the highly radioactive and rare 99 TcO 4 − due to their similar structure, charge density, and water solubility.The quantities of absorbed ReO 4 − on the materials were determined at the equilibrium state by varying the initial concentrations in the range of 10 to 300 ppm, using a material-to-solution ratio of 0.2 mg/mL.To ensure that the ion exchange had reached equilibrium, a reaction time of 12 h was employed.Figure 3a demonstrates that the sorption of ReO 4 − by all samples exhibits a rapid increase at low concentrations, followed by a notable slowdown as the sorption capacity of the adsorbent is approached.The Langmuir isotherm model provides the best fit for all these isotherms, with high correlation coefficients (>0.97), indicating a monolayer sorption mechanism (Figures S19−21, Table S2).Among the tested materials, CPN-3 demonstrates the highest maximum sorption capacity toward ReO 4 − , reaching 1282 mg/ g.This surpasses the sorption capacities of CPN-1 and CPN-2, which are 549 and 917 mg/g, respectively.The sorption capacities of these CPNs exhibit the following order: CPN-1 < CPN-2 < CPN-3.This observed trend aligns with the theoretical Cl − densities present in these materials.Also, the sorption capacity of CPN-3 is higher than the benchmark ReO 4 − sorbents with high sorption capacity including SCU-CPN-1 (876 mg/g), 36 TbDa-COF (952 mg/g), 26 CPN-tpm (1133 mg/g), 35 PS-COF-1 (1262 mg/g), 27 and TFAM-BDNP (998 mg/g) 30 (Table S4).The superhigh sorption capacity of CPN-3 can effectively prevent the generation of secondary waste and improve efficiency.Given the greatly enhanced performances with the increase of the anion concentration, we establish that the high density of the ion-exchange sites on the polymer backbone is the fundamental contributor to the high working capacity of CPN-3, and the mechanism for uptake of ReO 4 − is thus believed to be predominantly ion exchange.Sorption Kinetics Analysis.Subsequently, we conducted experiments to investigate the sorption kinetics of the three CPNs toward ReO − , surpassing 99.9%.This value is significantly higher than the removal rates observed for CPN-1 (90.0%) and CPN-2 (91.0%).These findings provide further evidence supporting the potential of enhancing the 99 S4).The calculated distribution coefficient (K d ) of CPN-3 is determined to be 7.0 × 10 7 mL/g.To the best of our knowledge, this value is only smaller than that of 3DCOF-g-BBPPh 3 Cl (1.0 × 10 8 mL/g) 46 and larger than the other benchmark 99 TcO 4 − /ReO 4 − sorbents such as SCU-CPN-4 (1.5 × 10 7 mL/g), 42 SCU-102 (5.6 × 10 5 mL/g), 17 SCU-100 (1.9 × 10 5 mL/g), 15 SCU-COF-1 (3.9 × 10 5 mL/g), 32 and VBCOP (4.0 × 10 5 mL/g) 47 (Figure 3c, Table S4).With its high K d value indicating excellent binding affinity, CPN-3 demonstrates great potential as an effective adsorbent for the removal of 99 TcO 4 − .Considering the rapid sorption kinetics observed for CPN-3 with ReO 4 − , we proceeded to investigate its sorption behavior toward 99 TcO 4 − .For this purpose, 20 mg of CPN-3 was immersed in a 20 mL aqueous solution containing 99 TcO 4 − at a concentration of 28 ppm, replicating the conditions employed in previously reported studies. 42The concentration of 99 TcO 4 − in the solution was monitored over time by measuring the time-dependent radioactivity using liquid scintillation counting (LSC).Figure 3b illustrates that CPN-3 rapidly adsorbed 99 TcO 4 − and achieved sorption equilibrium within just 1 min, with a removal rate exceeding 99.9%.These findings highlight the exceptional efficiency of CPN-3 in removing 99 TcO 4

−
. Furthermore, the adsorption kinetics for ReO 4 − by CPN-3 exhibited the same trend as that of 99 TcO 4 − under the same conditions, confirming the feasibility of using ReO 4 − as a surrogate (Figure 3b).The sorption kinetics of CPN-3 is truly remarkable, as it is comparable to the benchmark SCU-CPN-1 36 and SCU-CPN-4 42 and significantly faster than most of the reported sorbents (Table S4).For example, commercially available resins such as Purolite A532E and A530E were reported to require as long as 120 min to reach sorption equilibrium, 14 while the removal rate of inorganic material NDTB-1 was only 72% after 36 h of sorption. 12,13Even for crystalline cationic MOFs with uniform pore channels like SCU-103 48 and SCU-101, 19 the sorption equilibrium was achieved in a minimum of 5−10 min.The remarkable sorption kinetics of CPN-3 makes it particularly appealing for the emergency management of high-level radioactive waste.Its ability to rapidly adsorb 99 TcO 4 − enables a swift emergency response, effectively reducing the potential risks associated with accidental leakage.This advantage underscores the potential of CPN-3 in addressing urgent situations and enhancing the overall safety and security measures in place for handling high-level radioactive materials.

−
. The remarkable properties of CPN-3 make it a promising candidate for the remediation of 99 TcO 4 − in HLW streams, which are characterized by high ionic strengths.
Sorption after Treatment under High-Alkaline and Radiation Conditions.Considering the challenging conditions present in HLW streams, which involve strong ionizing fields (β, γ, neutron irradiations) and highly alkaline environments, sorbents must possess resistance to radiation and alkaline effects to be practically applicable.However, certain sorbents, like the commercially available Purolite A530E resin, despite exhibiting good sorption performance for the removal of TcO 4 − , suffer from poor radiation stability. 36This inherent drawback significantly limits its practical use for the removal of 99 TcO 4 − from HLW streams.Consequently, it is necessary to conduct a systematic assessment of CPN-3's adsorption capabilities toward ReO 4 − after treatment under high-alkalinity and irradiation conditions.Before initiating the adsorption experiments, the stability of CPN-3 under these harsh conditions was characterized using FT-IR spectroscopy.As depicted in Figure 4a, minimal changes were observed in the FT-IR spectra of CPN-3 even after treatment with 1 M NaOH aqueous solutions and subsequent exposure to 200 kGy of γradiation, thus confirming the structural integrity of CPN-3 under such severe conditions.We then conducted experiments to evaluate the ReO 4 − removal performance of CPN-3 after being treated with high-alkaline and radioactive conditions step by step.First, we immersed CPN-3 in water or NaOH aqueous solutions (1 M) and stirred the mixture for 24 h.The resulting material was then centrifuged and dried in a 60 °C oven for 4 h to obtain the water or NaOH-treated CPN-3.Then, the pristine, water-treated, and NaOH-treated CPN-3 were exposed to 100 and 200 kGy of γ-radiation, respectively, to obtain the radiation exposure samples.Both these samples were used for ReO 4 − sorption experiments.Figure 4b illustrates that the ReO 4 − adsorption capacity of NaOHtreated CPN-3 (1052 mg/g) is comparable to that of the pristine sample (1051 mg/g), indicating the excellent stability of CPN-3 under highly alkaline conditions.It is worth noting that most reported ReO 4 − sorbents exhibit decreased sorption capacities under the same alkaline conditions.For instance, SCU-CPN-1, SCU-CPN-2, and SCU-103 experience significant reductions in sorption capacities, dropping from 953, 1308, and 328 mg/g to 350, 429, and 73 mg/g, respectively. 42his significant decrease highlights the instability of these materials when exposed to highly alkaline conditions.Furthermore, the sorption capacity of NaOH-treated CPN-3 (1052 mg/g) surpasses the record-holding SCU-CPN-4 (∼437 mg/g) by 2.4 times, establishing a new record in ReO 4 − sorption capacity after treatment under high-alkaline conditions (Figure 4d). 42In addition, the sorption capacity of water-treated CPN-3 after exposure under 200 kGy of γradiation is almost the same as that of the pristine sample, demonstrating the excellent stabilities of these samples.For the samples treated with 1 M NaOH aqueous solutions and γradiation, a 22% decrease in the sorption capacities was observed, suggesting that part of the samples was destroyed under such conditions.However, the sorption capacity is still as high as 817 mg/g (Figure 4b).In addition, CPN-3 demonstrated a negligible decrease in the removal efficiency within a wide pH range of 2 to 12 (Figure 4c).The remarkable stability of CPN-3 under highly radioactive and alkaline conditions is attributed to the presence of alkyl chains formed through the free-radical polymerization of carbon−carbon double bonds.These alkyl chains play a crucial role in protecting the imidazole groups from ring-opening reactions caused by the attack of OH − ions, thereby enhancing the overall stability of the framework under such challenging conditions.The remarkable achievement further underscores the exceptional performance of CPN-3 as a highly stable and efficient sorbent for TcO 4 − removal, even in challenging highalkaline and radioactive environments.
Recyclability Investigation.The reusability of sorbents plays a vital role in their practical application, and to assess the reusability of CPN-3, a 1 M NaCl solution was utilized to elute ReO 4 − from the sorbents due to the strong competition of Cl − with ReO 4 − in anion exchange.Figure 4e illustrates that, during the initial sorption cycle, over 99.9% of ReO 4 − was effectively removed when 20 mg of CPN-3 was immersed in a 20 mL ReO 4 − solution (28 ppm) and stirred for 2 h.Subsequently, washing CPN-3 with a 1 M NaCl solution successfully stripped off over 99% of the captured ReO 4 − .The regenerated CPN-3 demonstrated exceptional recyclability, maintaining a removal efficiency exceeding 99% even after six cycles.This outstanding reusability highlights CPN-3's capability for efficient sequestration of 99  − removal (Table S5).Notably, CPN-3 exhibited exceptional performance, removing over 72 and 84% of 99 TcO 4 − at solid/liquid ratios of 5 and 10 g/L, respectively, surpassing the capabilities of SCU-CPN-2 (67%, 5 g/L), 49 NDTB-1 (13%, 5 g/L), 13 SCU-COF-1 (62.8, 10 g/ L), 32 and SCU-101 (75.2%, 10 g/L) 19 (Figure 4f and Table S7).Furthermore, column sorption tests using a simulated Hanford LAW stream demonstrated that an ion-exchange chromatographic column packed with 200 mg of CPN-3 effectively removed nearly all of the ReO 4 − from the initial 32 mL of the waste solution, indicating high removal efficiency (Figure 4h).To expand the potential application of CPN-3 in nuclear waste remediation, we tested its capability for decontaminating 99 S6).In simulated SRS waste, the removal of TcO 4 − by CPN-3 reached 68% at a solid/liquid ratio of 40 g/L, lower than those of SCU-CPN-4 (94.3%, 20 g/ L), 42 Ag-TPPE (90.0%, 10 g/L), 50 and SCU-103 (90.0%, 40 g/L) 48 (Figure 4f, Table S7).It is important to emphasize that dealing with Hanford LAW and SRS HAW waste requires a substantial quantity of adsorbents, often measured in tons, making the cost of materials and scalability crucial factors that are currently widely overlooked.The laboratory synthesis cost of CPN-3 is estimated to be 3 USD/g, and its simple synthesis steps allow for easy upscaling, leading to further cost reduction.In contrast, other highly efficient 99 TcO 4 − /ReO 4 − adsorbents mentioned in the literature, like Ag-TPPE, SCU-CPN-4, and SCU-103, suffer from complex organic ligand/monomer synthesis processes, expensive reaction materials, and challenging large-scale production, making them impractical for realworld applications.With exceptional structural stability,  − and the binding sites on CPN-3 were further investigated by using L 3 -edge X-ray absorption fine spectroscopy (XAFS).The Re L 3 -edge X-ray absorption near-edge structure (XANES) spectra revealed that the absorption edge position for ReO 4 − adsorbed on CPN-3 was 10 541 eV, which closely matched that of NH 4 ReO 4 (10 540 eV), 51 indicating that the presence of Re in the +7 oxidation state (Figure S25).In the corresponding Re L 3 -edge R-spaceextended XAFS (EXAFS) spectra, a single prominent peak at approximately 1.35 Å (not phase shift corrected) was observed.This peak could be accurately fitted using a Re−O scattering path, indicating that the adsorption of ReO 4 − occurred in the form of the ReO 4 − anion (Figure 5a).The FT-IR spectra of CPN-3, CPN-3@ReO 4 − , and KReO 4 are presented in Figure 5b.It is evident from the spectra that the presence of ReO 4 − adsorption is characterized by a well-defined band at 902 cm −1 in the spectrum of CPN-3@ReO 4 − , which is notably absent in the spectrum of CPN-3.This distinctive band can be attributed to the symmetric Re−O stretching vibration, as documented by previous studies. 52In comparison to the spectrum of KReO 4 , the band center of the ν(ReO 4 ) peak exhibits a noticeable upward (blue-) shift of +6 cm −1 .Additionally, the line width of the ν(ReO 4 ) vibration in CPN-3@ReO 4 − is considerably reduced, providing a clear indication that the ReO 4 − cluster is confined to well-distributed and localized binding sites within the network.Careful examination of CPN-3 spectra before and after adsorbing ReO 4 − reveals subtle changes to its phonon modes of the azole ring, e.g., intensity of the ν(C=C) mode diminished and the δ(CH) mode blueshifted by 8 cm −1 (Figures 5b, S6).In contrast, the phenyl ring modes ν(C=C) and δ(CH), which were previously shown to be sensitive to the chemical environment change, remain in the same position. 53,54All of these findings point to the fact that ReO 4 − interacts primarily with the azole ring of CPN-3.XPS analysis is used to further analyze the ReO 4 − adsorption site on CPN-3.The observation of the Re 4f signal and the attenuation of Cl 2p peak in the survey spectrum of CPN-3@ReO 4 − further demonstrate that the Re (VII) oxidation state exists before and after adsorption and the adsorption of ReO 4 − followed by anion exchange (Figure 5c).The peak corresponding to Re 4f 7/2 undergoes a shift from 45.9 eV in the case of ReO 4 − to 45.4 eV in the case of CPN-3@ReO 4

−
, while a similar phenomenon is observed in the shift of the O 1s peak attributed to Re−O − from 531.3 eV for ReO 4 − to 530.6 eV for CPN-3@ReO 4 − (Figure 5d,e).These shifts in peak positions suggest that the electron density of ReO 4 − experiences a slight increase following its interaction with the CPN-3 framework, a change that is likely facilitated by the presence of imidazolium units in the pores of CPN-3, which can provide positive charges to counterbalance the negatively charged ReO 4 − species.A noteworthy observation in the XPS spectrum of CPN-3@ReO 4 − is the emergence of a new peak at 399.8 eV, corresponding to the N + −O − species, providing further confirmation that the primary adsorption sites are the N + moieties within the imidazolium units (Figure 5f).Similar phenomena have been observed in a published work. 55ensity functional theory (DFT) calculations were further conducted to investigate the mechanisms behind the remarkable alkaline stability of CPN-3 and its superior separation capability toward 99 TcO 4 − .−40 Figure 6a illustrates the widely accepted ring-opening pathway of the imidazolium ring under alkaline conditions, which can be applied to describe the degradation of imidazolium-based CPNs.Two fragments, labeled Fragments 1 and 2, were selected to simulate the properties of two specific sorbents.Fragment 1 represents SCU-CPN-1, a highly efficient 99 TcO 4 − sorbent that is known to be unstable in alkaline conditions. 42n the other hand, Fragment 2 represents CPN-3, the sorbent reported in this study, which exhibits excellent stability in alkaline solutions.Figure 6b,c illustrates the ring-opening reaction pathway of the imidazole unit for Fragments 1 and 2, respectively.The adsorption of OH − onto the imidazole ring in both Fragment 1 and Fragment 2 is an exothermic process, releasing energy of 120.7 and 118.9 kcal/mol, respectively.Subsequently, another free OH − species approaches and reacts with OH − adsorbed on the imidazole ring, leading to the formation of a water molecule.In the case of Fragment 1, this reaction exhibits a Gibbs energy barrier of 13 kcal/mol, whereas for Fragment 2, the barrier is higher at 17.6 kcal/mol, suggesting that the OH − attack to form H 2 O is more kinetically demanding for Fragment 2. The ring-opening reaction proceeds with the assistance of water molecules.In the case of Fragment 1, the calculated Gibbs free reaction energies are −8.6 and −13.0 kcal/mol for the two plausible ring-opening scenarios, and no transition state is found.The ring-opening process is continuous, exothermic, and spontaneous.This indicates that imidazole cations in Fragment 1 exhibit high instability in alkaline solutions and are prone to undergoing ring-opening reactions, which aligns with the experimental observations.In contrast, for Fragment 2, the Gibbs free energies of activation for both types of ring-opening reactions are significantly high, measuring 27.6 and 45.1 kcal/ mol, respectively, as depicted in Figure 6c.Additionally, our calculations reveal that the ring-opening steps in Fragment 2 are endergonic, with Gibbs free reaction energies of +9.0 and +18.0 kcal/mol.Therefore, the presence of the bulk alkyl chain in Fragment 2 thermodynamically and kinetically inhibits the ring-opening process of imidazole rings, thus providing Fragment 2 with exceptional stability in alkaline solutions.These findings align with the experimental observations.
DFT calculations were then conducted to reveal the excellent selectivity of CPN-3 toward 99 TcO 4 − over other ions such as NO 3 − and SO 4 2− . As mentioned above, the imidazolium unit serves as the primary sorption site, and M + (representing the cation) was chosen as the model for the calculations.Initially, we examined the electrostatic potential (ESP) of M + and studied that of 99  , and M + TcO 4 − and determined their respective binding energy (ΔE) values.The results, depicted in Figure 6e, reveal that the primary adsorption sites for all three anions are located in the proximity of the positively charged imidazolium unit, consistent with experimental observations.Notably, despite exhibiting similar sorption sites on the M + fragment, the corresponding ΔE values show distinct differences.Specifically, the calculated ΔH value for M + TcO 4 − is determined to be − 19.

■ CONCLUSIONS
In summary, a cationic polymeric nanotrap called CPN-3 was designed and synthesized to address the challenges associated with alkaline nuclear waste management.CPN-3 was meticulously engineered by maximizing the density of counteranions and incorporating a superhydrophobic alkyl chain at the N3 position of the key imidazolium moiety.This sophisticated design approach resulted in CPN-3 possessing exceptional alkaline resistance, attributed to the presence of the alkyl chain, as well as enhanced hydrophobicity, leading to improved selectivity toward 99 TcO 4 − .The studies conducted on CPN-3 revealed its outstanding sorption properties, which encompassed fast sorption kinetics, high sorption capacity, excellent sorption selectivity, complete reusability, and remarkable sorption performance even under highly alkaline aqueous solutions.These notable features make CPN-3 a highly promising candidate for the efficient removal of 99 TcO 4 − from alkaline nuclear waste, thereby offering a new avenue for addressing the persistent challenges encountered in the CARBEX process and alkaline nuclear waste management.

TcO 4 −−■
/ReO 4 − .Furthermore, the flexible and hierarchical pore structure of CPNs facilitates mass transfer, promoting sorption kinetics.As a proof of concept, we report in this contribution the preparation of a series of monomers with controlled numbers of imidazolium units based on the quaternization reaction between the 1-vinyl-1Himidazole and benzene ring with different benzyl bromide substituents.Through a subsequent free-radical polymerization reaction and ion exchange with a NaCl solution, a series of CPNs with controllable anion densities, named CPN-1, -2, and -3, were obtained.The theoretical anion density increases as the number of imidazolium units increases.Additionally, the aliphatic carbon chains on N3 of the imidazolium unit, generated through free-radical polymerization, play a protective role in shielding the imidazolium from attacks by OH − groups.CPN-3, with the highest anion density, exhibits the highest maximum adsorption capacity of 1282 mg/g toward ReO 4− among the three materials.Also, CPN-3 has excellent chemical stability, and its adsorption toward ReO 4 − can be well-retained after treatment with 1 M NaOH aqueous solutions and 200 kGy γ-ray radioactivity.It showed an alltime ReO 4 − adsorption record of 1050 mg/g after being treated with 1 M NaOH solutions for 24 h.Moreover, CPN-3 demonstrates excellent performance in the removal of 99 TcO 4 from simulated Hanford and SRS waste streams and has low material cost compared to the benchmark 99 TcO 4 − sorbents, which makes it attractive for direct removal of 99 TcO 4 − from legacy nuclear waste streams.Examination studies and density functional theory (DFT) calculations undisputedly reveal the mechanisms behind the remarkable alkaline stability of CPN-3 and its superior separation capability toward 99 TcO 4 − .RESULTS AND DISCUSSION Design, Synthesis, and Characterizations.Ion exchange is a widely recognized mechanism for the efficient adsorptive removal of 99 TcO 4 − /ReO 4 − from water, where the density of anions present within the material's framework plays a significant role in enhancing the adsorption capacity of

4 −
. Initially, 20 mg of each CPN was immersed in 100 mL of aqueous solution containing ReO 4 − with a concentration of 28 ppm.As illustrated in Figures S22− 24, all three materials reached sorption equilibrium in approximately 15 min.Interestingly, CPN-3 exhibited an outstanding removal efficiency of ReO 4 TcO 4 − /ReO 4 − adsorption performance by improving the anion density in the system.The sorption data can be accurately described by the pseudo-second-order model, with CPN-3 exhibiting a k 2 value of 4.10 × 10 −2 g mg −1 min −1 .The value surpasses the respective k 2 values of 3.98 × 10 −3 g mg −1 min −1 for CPN-1 and 5.36 × 10 −3 g mg −1 min −1 for CPN-2 (Figures S22−24 and Table

TcO 4 −
/ReO 4 − in nuclear waste management.Dynamic Separation Experiments.To evaluate the sorption performance of CPN-3 in practical applications, dynamic sorption experiments were conducted by using CPN-3 as a filler.Considering the exceptional sorption capacity and rapid sorption rate of CPN-3 for ReO 4 − , we utilized 40 mg samples to conduct this breakthrough experiment.A prepared ReO 4 − aqueous solution with a concentration of 28 ppm was introduced into the column at a flow rate of 4.0 mL/min.As shown in Figure 4g, a significant portion of ReO 4 − was removed, with a residual concentration (C f /C 0 ) less than 5% after passing through 200 mL of the waste solution.This indicates that CPN-3 can treat a mass of ReO 4 − solution approximately 5000 times its own mass.The high removal efficiency observed can be attributed to the ultrafast sorption kinetics of CPN-3.The rapid sorption rate allows for an impressive removal efficiency even in a flowing solution.As the solution flowed through the column, the concentration of ReO 4 − in the effluent gradually increased.The dynamic separation results highlight the excellent practical application potential of CPN-3 in the treatment of radioactive waste containing 99 TcO 4 − .Removal from Simulated Nuclear Wastes.The rapid kinetics, high adsorption capacity, and exceptional selectivity of CPN-3 prompted us to explore its performance in addressing legacy nuclear waste challenges.Previous evaluations of Hanford tank waste inventories have indicated the necessity of significantly reducing technetium levels to prepare immobilized low-activity waste (ILAW) glass that fulfills performance assessment requirements.To investigate the removal of 99 TcO 4 − for this purpose, we conducted experiments using a simulated Hanford LAW wastewater solution.The concentrations of NO 3 − (5.96 × 10 −2 M), NO 2 − (3.03 × 10 −3 M), and Cl − (6.93 × 10 −2 M) were intentionally maintained at over 300 times higher levels than that of 99 TcO 4 − (1.94 × 10 −4 M), creating a formidable challenge for selective 99 TcO 4

Figure 6 .
Figure 6.(a) Degradation of the imidazolium unit by the ring-opening mechanism.The DFT calculated ring-opening mechanism and the corresponding Gibbs energy profiles of Fragment 1 (b) and Fragment 2 (c) by the attack of OH − in alkaline solutions.(d) ESP distribution on the electron density surface (isodensity = 0.001 au) of the M + fragment (top) and 99 TcO 4 − (bottom).(e) Optimized structures of M + TcO 4 − (left), M + NO 3 − (middle), and M + SO 4 2− (right).ΔE represents the binding energy.
TcO 4 − for comparison purposes.It is not surprising that the electron density van der Waals surface near the imidazole rings of M + exhibited a relatively concentrated positive ESP distribution (Figure 6d top).The electron density near the oxygen atoms of 99 TcO 4 − displayed a relatively concentrated negative ESP distribution (Figure 6d bottom).This mutual attraction between the positive and negative charges is considered to be the intrinsic reason for the excellent adsorption performance of CPN-3 toward 99 TcO 4 − .We then optimized the structures of M + NO 3 − , M + SO 4 2−