Structural and computational characterization of a bridging zwitterionic-amidoxime uranyl complex

Abstract: A bridging (μ2) neutral zwitterionic amidoxime binding mode previously unobserved between amidoximes and uranyl is reported and compared to other uranyl amidoxime complexes.

“…Similar cases of metal ion binding leading to displacement of a tautomeric equilibrium have been seen in uranyl ion complexes of amidoximes, where the ligand is bound in its neutral but zwitterionic form obtained by proton transfer from O to oxime-N. 19,20 Somewhat surprisingly therefore, these principles have not been explored for more complex dynamic aggregates in solution and in two dimensions on a flat surface, even though structurally distinct supramolecular assemblies can be efficiently studied in submolecular detail with scanning probe techniques. 21,22 In seeking to explore enhancement of metal ion effects on a tautomeric equilibrium, we have examined the coordination behavior of the 2-pyridone-derived ligand H 2 L ( Fig.…”

Influencing prototropy by metal ion coordination: supramolecular transformation of a dynamer into a Zn-based toroidal species

“…Similar cases of metal ion binding leading to displacement of a tautomeric equilibrium have been seen in uranyl ion complexes of amidoximes, where the ligand is bound in its neutral but zwitterionic form obtained by proton transfer from O to oxime-N. 19,20 Somewhat surprisingly therefore, these principles have not been explored for more complex dynamic aggregates in solution and in two dimensions on a flat surface, even though structurally distinct supramolecular assemblies can be efficiently studied in submolecular detail with scanning probe techniques. 21,22 In seeking to explore enhancement of metal ion effects on a tautomeric equilibrium, we have examined the coordination behavior of the 2-pyridone-derived ligand H 2 L ( Fig.…”

Influencing prototropy by metal ion coordination: supramolecular transformation of a dynamer into a Zn-based toroidal species

“…The O b –O b bond is broken, due to the long distance (2.468 Å), and meanwhile the U–U and U–O b distances are significantly shortened to 3.389 and 2.096 Å, respectively. This situation is commonly observed in uranyl polymeric complexes, such as the dihydroxyl binding to uranyl in K 12 [(UO 2 ) 6 (O 2 ) 9 (OH) 6 ]· x H 2 O complexes, , and the diamidoximo binding to uranyl in (UO 2 ) 2 (NO 3 ) 4 (μ 2 -benzyl-amidoxime) 2 ·H 2 O, which provides further linkers for the polymeric formation. In the third isomer, two bridged O b atoms form a superoxide moiety with an O b –O b bond length of 1.309 Å; thus, the distance of U–O b increases to 2.508 Å, implying weak interaction between uranyl and the 2 O 2 1– unit.…”

Electronic Structures and Unusual Chemical Bonding in Actinyl Peroxide Dimers [An₂O₆]²⁺ and [(An₂O₆)(12-crown-4 ether)₂]²⁺ (An = U, Np, and Pu)

“…The first binding motif displays both acetamidoxime and benzamidoxime molecules with an η 1 -O binding through the oxygen atom in the oxime functional group . The second binding motif involves side-on η 2 binding through the N–O bond of the amidoxime functionality, which was shown to be the most stable binding by density functional theory. − A third binding motif was recently reported with the first dinuclear AO–uranyl complex, where the uranyl metal centers were bridged by two zwitterionic benzamidoxime molecules through the μ 2 -O atom of the oxime . While the reported AO–uranyl structures are good references for possible binding motifs, they are not representative of the AO–uranyl complexes on the surface of AO-PAN mat,s where there is a prevalence of hydrolysis effects and high amidoxime to uranyl molar ratios, causing considerable amounts of amorphous precipitation on the surface of the AO-PAN mat during uranyl uptake experiments.…”

“…33−36 A third binding motif was recently reported with the first dinuclear AO−uranyl complex, where the uranyl metal centers were bridged by two zwitterionic benzamidoxime molecules through the μ 2 -O atom of the oxime. 31 While the reported AO−uranyl structures are good references for possible binding motifs, they are not representative of the AO−uranyl complexes on the surface of AO-PAN mat,s where there is a prevalence of hydrolysis effects and high amidoxime to uranyl molar ratios, causing considerable amounts of amorphous precipitation on the surface of the AO-PAN mat during uranyl uptake experiments. The hydrolysis effects typically result in bridging μ 2 -OH or μ 3 -O ligands between uranyl metal centers, creating oligomeric species and promoting surface precipitation.…”

“…Identification of the AO–uranyl binding motifs and uranyl speciation on the AO-PAN mat surface requires a thorough elucidation of small-molecule AO–uranyl model complexes. , A total of three different binding motifs has been reported on the basis of experimental findings and deposited crystal structures, but a systematic understanding of the related spectral signals has not been provided in the literature. The first binding motif displays both acetamidoxime and benzamidoxime molecules with an η 1 -O binding through the oxygen atom in the oxime functional group .…”

Uranyl Speciation on the Surface of Amidoximated Polyacrylonitrile Mats