Involvement of 5f Orbitals in the Covalent Bonding between the Uranyl Ion and Trialkyl Phosphine Oxide: Unraveled by Oxygen K-Edge X-ray Absorption Spectroscopy and Density Functional Theory

Zhang, Yusheng; Duan, Wuhua; Yang, Yuning; Jian, Tian; Qiao, Yusen; Ren, Guoxi; Zhang, Nian; Zheng, Lei; Yan, Wensheng; Wang, Jianchen; Chen, Jing; Minasian, Stefan G.; Sun, Taoxiang

doi:10.1021/acs.inorgchem.1c02236

Cited by 10 publications

(25 citation statements)

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“…Actinide-ligand covalency has been studied using a variety of experimental techniques, including X-ray absorption spectroscopy, − X-ray crystallography, − NMR spectroscopy, − EPR spectroscopy, − and optical spectroscopy. − With respect to optical spectroscopy, complexes with the 5f 1 electronic configuration have proven to be especially useful. ,− The lack of electron–electron repulsion in this configuration allows the spin–orbit coupling to be treated in a relatively straightforward manner. , For example, in 2013, we reported a comprehensive bonding analysis of a series of O h -symmetric 5f 1 complexes, including [U V (CH 2 SiMe 3 ) 6 ] − , [U V (O t Bu) 6 ] − , and [U V X 6 ] − (X = F, Cl, Br), which permitted an estimate of the strengths of the ligand–f-orbital interactions. More recently, Liddle and co-workers analyzed the optical and EPR spectra of the C 3v -symmetric U(V) nitride, [U V (Tren TIPS )(N)] − (Tren TIPS = N (CH 2 CH 2 N Si i Pr 3 ) 3 ), and extracted the corresponding crystal field splitting parameters .…”

Section: Introductionmentioning

confidence: 99%

Evaluating f-Orbital Participation in the U^V═E Multiple Bonds of [U(E)(NR₂)₃] (E = O, NSiMe₃, NAd; R = SiMe₃)

et al. 2023

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The reaction of 1 equiv of 1-azidoadamantane with [U III (NR 2 ) 3 ] (R = SiMe 3 ) in Et 2 O results in the formation of [U V (NR 2 ) 3 (NAd)] (1, Ad = 1-adamantyl) in good yields. The electronic structure of 1, as well as those of the related U(V) complexes, [U V (NR 2 ) 3 (NSiMe 3 )] (2) and [U V (NR 2 ) 3 (O)] (3), were analyzed with EPR spectroscopy, SQUID magnetometry, NIR−visible spectroscopy, and crystal field modeling. This analysis revealed that, within this series of complexes, the steric bulk of the E 2− (E�O, NR) ligand is the most important factor in determining the electronic structure. In particular, the increasing steric bulk of this ligand, on moving from O 2− to [NAd] 2− , results in increasing U�E distances and E−U−N amide angles. These changes have two principal effects on the resulting electronic structure:(1) the increasing U�E distances decreases the energy of the f σ orbital, which is primarily σ* with respect to the U�E bond, and (2) the increasing E−U−N amide angles increases the energy of f δ , due to increasing antibonding interactions with the amide ligands. As a result of the latter change, the electronic ground state for complexes 1 and 2 is primarily f φ in character, whereas the ground state for complex 3 is primarily f δ .

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Section: Introductionmentioning

confidence: 99%

Evaluating f-Orbital Participation in the U^V═E Multiple Bonds of [U(E)(NR₂)₃] (E = O, NSiMe₃, NAd; R = SiMe₃)

et al. 2023

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“…Together, these results indicate that electrochemically generated PO Cb 2− selectively captures UO 2 2+ from a mixed alkali, lanthanide, and actinide aqueous phase. While the nature of this selectivity remains under investigation, we suspect that optimal covalent bonding interactions between the PO units and the U center – very recently investigated in the PUREX context 29,30 – are likely at play.…”

Section: Resultsmentioning

confidence: 93%

Selective electrochemical capture and release of uranyl from aqueous alkali, lanthanide, and actinide mixtures using redox-switchable carboranes

et al. 2022

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“…4 For instance, only very recently have TRPO derivatives been identified to have excellent binding to uranyl (UO 2 2+ ) due to optimized covalency and the involvement of the U 5f orbitals. 5 We have previously shown that redox-switchable ortho-closocarboranes bearing coordinating phosphine oxide donors, 1,2-(Ph 2 PO) 2 -1,2-C 2 B 10 H 10 ( PO Cb), could be electrochemically reduced to the nido-carborane, PO Cb 2− , an efficient extractant for biphasic UO 2 2+ capture (Figure 1a). Release of UO product back to its closo ( PO Cb) form.…”

Section: ■ Introductionmentioning

confidence: 97%

“…In most cases, however, phosphine oxide-based extractants are most effective at capturing actinides, but there remains a surprising knowledge gap in the literature between structure–activity relationships of the ligands and corresponding UO 2 2+ extraction properties . For instance, only very recently have TRPO derivatives been identified to have excellent binding to uranyl (UO 2 2+ ) due to optimized covalency and the involvement of the U 5f orbitals …”

Section: Introductionmentioning

confidence: 99%

Tuning Phosphine Oxide-Substituted ortho-Carboranes for Improved Biphasic Electrochemical UO₂²⁺ Capture and Release

Heinrich,

Benhaim,

Mattejat

et al. 2023

Inorg. Chem.

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We report the synthesis and characterization of a series of new, tunable 1,2-bis(diarylphosphine oxide)-ortho-carboranes, derivatives of our previously reported uranyl (UO2 2+) capture agent 1,2-(Ph2PO)2-1,2-C2B10H10 ( PO Cb). The series features new cage-substituted variants of PO Cb, namely, 9-I-POCb ( PO CbI), 9,12-I2-POCb ( PO CbI 2 ), 9,12-Me2-POCb ( PO CbMe 2 ), 9,12-Et2-POCb ( PO CbEt 2 ), and 4,5,7,8,9,10,11,12-Me8-POCb ( PO CbMe 8 ). Aryl-substituted variants include 1,2-((4-MeO-Ph)2PO)2-Cb ( (OMe)PO Cb) and 1,2-((4-F-Ph)2PO)2-Cb ( (F)PO Cb). The effects of electron-withdrawing (EWG) and electron-donating (EDG) groups on resulting carborane redox potentials were assessed using electrochemical means, and the resulting Lewis basicities were quantified using empirical and competition-based NMR experiments. In organic solution, carboranes substituted with EWGs exhibited weaker coordination to UO2 2+, whereas those with EDGs exhibited stronger coordination. Similar to the previously reported unsubstituted POCb, the tunable new series of carboranes were electrochemically reduced and used for the biphasic capture of UO2 2+ from an aqueous to an organic phase and back again (release) through electrochemical oxidation. Extraction and back-extraction efficiencies were determined by analyses of the aqueous phases by ICP-OES. While all reduced nido-carboranes efficiently extracted UO2 2+ in high yields (78–88%)with seemingly no correlation to the aforementioned measured Lewis basicitieswe found the back-extraction of UO2 2+ to be significantly improved from POCb and, surprisingly, more closely related to their hydrophobic rather than their Lewis basic properties.

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Involvement of 5f Orbitals in the Covalent Bonding between the Uranyl Ion and Trialkyl Phosphine Oxide: Unraveled by Oxygen K-Edge X-ray Absorption Spectroscopy and Density Functional Theory

Cited by 10 publications

References 102 publications

Evaluating f-Orbital Participation in the U^V═E Multiple Bonds of [U(E)(NR₂)₃] (E = O, NSiMe₃, NAd; R = SiMe₃)

Evaluating f-Orbital Participation in the U^V═E Multiple Bonds of [U(E)(NR₂)₃] (E = O, NSiMe₃, NAd; R = SiMe₃)

Selective electrochemical capture and release of uranyl from aqueous alkali, lanthanide, and actinide mixtures using redox-switchable carboranes

Tuning Phosphine Oxide-Substituted ortho-Carboranes for Improved Biphasic Electrochemical UO₂²⁺ Capture and Release

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Involvement of 5f Orbitals in the Covalent Bonding between the Uranyl Ion and Trialkyl Phosphine Oxide: Unraveled by Oxygen K-Edge X-ray Absorption Spectroscopy and Density Functional Theory

Cited by 10 publications

References 102 publications

Evaluating f-Orbital Participation in the UV═E Multiple Bonds of [U(E)(NR2)3] (E = O, NSiMe3, NAd; R = SiMe3)

Evaluating f-Orbital Participation in the UV═E Multiple Bonds of [U(E)(NR2)3] (E = O, NSiMe3, NAd; R = SiMe3)

Selective electrochemical capture and release of uranyl from aqueous alkali, lanthanide, and actinide mixtures using redox-switchable carboranes

Tuning Phosphine Oxide-Substituted ortho-Carboranes for Improved Biphasic Electrochemical UO22+ Capture and Release

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Evaluating f-Orbital Participation in the U^V═E Multiple Bonds of [U(E)(NR₂)₃] (E = O, NSiMe₃, NAd; R = SiMe₃)

Evaluating f-Orbital Participation in the U^V═E Multiple Bonds of [U(E)(NR₂)₃] (E = O, NSiMe₃, NAd; R = SiMe₃)

Tuning Phosphine Oxide-Substituted ortho-Carboranes for Improved Biphasic Electrochemical UO₂²⁺ Capture and Release