Synthesis of DtBuCH18C6-coated magnetic metal–organic framework Fe3O4@UiO-66-NH2 for strontium adsorption

“…When the equilibrium concentration of Sr 2+ was at 380 mg L −1 , the maximum adsorption equilibrium capacity of ZrP/18C6 for Sr 2+ was obtained to be 195.74 mg g −1 , which was 4.5 times higher than that of α-ZrP at 43.03 mg g −1 . It can be seen that ZrP/18C6 attains a higher adsorption capacity than the general zirconium phosphate-based materials 12 and crown ether-based materials, 14 indicating a better adsorption potential. This suggests that intercalation of 18-crown-ether-6 into zirconium phosphate leads to the formation of many binding sites for Sr 2+ .…”

“…3(b) shows that the C 1s peak can be deconvoluted to three peaks at 284.80 eV, 286.30 eV, and 288.73 eV, respectively, indicating carbon exists in three different states of C–C/C–H, C–OH, and C–O–C, respectively. 14 Fig. 3(c) presents deconvolution of the O 1s peak to three types of peaks at 531.11 eV, 532.55 eV and 533.43 eV.…”

“…The main methods studied include chemical precipitation, 5 solvent extraction, 6,7 membrane treatment, 8,9 biological methods, 10,11 and adsorption methods. [12][13][14] Among these methods, the adsorption method has advantages over other methods in treatment efficiency, chemical reagent dosage, and separation cost. Therefore, in the last decades, a lot of adsorbents have been developed.…”

High strontium adsorption performance of layered zirconium phosphate intercalated with a crown ether

“…When the equilibrium concentration of Sr 2+ was at 380 mg L −1 , the maximum adsorption equilibrium capacity of ZrP/18C6 for Sr 2+ was obtained to be 195.74 mg g −1 , which was 4.5 times higher than that of α-ZrP at 43.03 mg g −1 . It can be seen that ZrP/18C6 attains a higher adsorption capacity than the general zirconium phosphate-based materials 12 and crown ether-based materials, 14 indicating a better adsorption potential. This suggests that intercalation of 18-crown-ether-6 into zirconium phosphate leads to the formation of many binding sites for Sr 2+ .…”

“…3(b) shows that the C 1s peak can be deconvoluted to three peaks at 284.80 eV, 286.30 eV, and 288.73 eV, respectively, indicating carbon exists in three different states of C–C/C–H, C–OH, and C–O–C, respectively. 14 Fig. 3(c) presents deconvolution of the O 1s peak to three types of peaks at 531.11 eV, 532.55 eV and 533.43 eV.…”

“…The main methods studied include chemical precipitation, 5 solvent extraction, 6,7 membrane treatment, 8,9 biological methods, 10,11 and adsorption methods. [12][13][14] Among these methods, the adsorption method has advantages over other methods in treatment efficiency, chemical reagent dosage, and separation cost. Therefore, in the last decades, a lot of adsorbents have been developed.…”

High strontium adsorption performance of layered zirconium phosphate intercalated with a crown ether

“…[22] And the absorption peak located at 1260 cm À 1 is ascribed to the stretching vibration of CÀ N. [29] The absorption peaks appeared in 768 cm À 1 and 665 cm À 1 are the absorption peak of ZrÀ O. [30] And the feature peak at approximately 3300 cm À 1 is corresponding to the absorption peak of NÀ H. [29] In nitrogen adsorption and desorption isotherms (Figure 2f), TiO 2 hollow spheres display a type IV isotherm shape, which rises abruptly in the high-pressure region with a hysteresis loop of type H4. [31] With the growth of UiO-66-NH 2 particles, the adsorption uptake of composites in the low-pressure region increased rapidly with a typical isotherm shape of type I, which is similar to that of pure UiO-66-NH 2 crystals.…”

Adsorption‐Induced In‐Situ Construction of TiO₂ Hollow Sphere/UiO‐66‐NH₂ Heterostructures with Boosted Photocatalytic Activity toward Cr(VI) Reduction

“…Then, it was transferred into an oil bath thermostated at a temperature of 80 • C, 12 mL of ammonia solution (25%, w/w) was quickly added to the solution, and stirred for 2 h. Finally, the Fe 3 O 4 nanoparticles were collected by an external magnet. They were washed with 10 mL water:ethanol mixture (1:1, v/v) and dried in an oven at 80 • C for 6 h. The synthesized Fe 3 O 4 nanoparticles were functionalized using MAA according to literature [34]. In the following, the magnetic MOF was synthesized using the previously reported study with some modifications [20].…”

Selective extraction of apixaban from plasma by dispersive solid‐phase microextraction using magnetic metal organic framework combined with molecularly imprinted polymer nanocomposite