Periodic Trends in Actinyl Thio-Crown Ether Complexes

Hu, Shu‐Xian; Liu, Jingjing; Gibson, John K.; Li, Jun

doi:10.1021/acs.inorgchem.7b03277

Cited by 29 publications

(38 citation statements)

References 84 publications

(148 reference statements)

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“…The same orbital occupation occurs in the 9 A g state of Np 2 O 2 with the valence electronic structure of 4 a g 2 (f) 4 (f) 4 , where the doubly occupied 4 a g bonding orbital is evidently hybridized from Np 6 d x2-y2 and 7 s AOs, and the corresponding unoccupied 4 b 1u * antibonding orbitals from coaxial Np 6 d x2-y2 are also hybridized with 7 s AOs. With similarity of the electronic structures, in the 13 A g state of Bk 2 O 2 the 3 a g HOMO and 4 b 1u LUMO are, as expected, composed of the 7 s/6 d hybrid AOs from two Bk atoms. For the 11 B 1u state of Cf 2 O 2 , the filled 4 a g MO is also the HOMO of the molecule and consists of 82 % 7 s and 10 % 6 d AOs.…”

Section: Pa 2 Osupporting

confidence: 78%

“…[10] In this bonding model, 6 d orbitals take part in bonding with ligands and 5 f orbitals mainly keep non-bonding electrons. [11] This scenario could explain the chemical bonding in actinyl coordination complexes of organic ligands, such as AnO 2 (18-crown-6) [12] and UO 2 (12-thio-crown-4), [13] which could also exist in low-valence actinide compounds, especially in americium(II) compounds with negligible 5 f orbitals involving in chemical bonding. In addition, the participant of f orbitals in chemical bonding has been observed to be able to direct the compound structure.…”

Section: Introductionmentioning

confidence: 99%

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Electronic Structures and Properties of Actinide‐Bimetal Compounds An₂O₂ (An=Th to Cf) and U₂E₂ (E=N, F, S)

et al. 2021

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In this study, we investigated the geometry structure and the chemical bonding of actinide clusters An 2 O 2 by quantum chemistry calculations. Through the geometry searching for An 2 O 2 clusters with the combination of considerable initial structures and spin states, it is found that a novel ground-state structure of quasi-linear type for Pa 2 O 2 compares with a rhombic structure for the rest of An 2 O 2 clusters. Due to the more extended 5 f orbitals, the PaÀ Pa bond is verified to be a triple bond by the electronic configuration and the bond order analysis, which brings the quasi-linear structure of Pa 2 O 2 and distinguishes it from the rhombic ones. For both kinds of ground-state structures, the participation of 5 f orbitals in the AnÀ O bonds stabilizes the structures further. Owing to spinorbit coupling, the ground-state structure of U 2 O 2 changes from the linear one at the SR level to the rhombic one with SO into consideration. Further investigations on clusters U 2 E 2 with different ligands reveal that the quasi-linear U 2 F 2 has an equivalent quadruple bond. The decline of the bonding electrons of the UÀ U bond, the foremost causes for the change of the structures and illustrates the decrease of the UÀ U bond strength. Our investigations on An 2 O 2 and U 2 E 2 compounds provide some insights into the role of 5 f orbital in the chemical bonding of actinide compounds and f-f bonding in multiple bonding.

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Section: Pa 2 Osupporting

confidence: 78%

Section: Introductionmentioning

confidence: 99%

Electronic Structures and Properties of Actinide‐Bimetal Compounds An₂O₂ (An=Th to Cf) and U₂E₂ (E=N, F, S)

et al. 2021

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“…14 As a result, crown ethers have potential for actinide partitioning from nuclear waste, [15][16] particularly via size-specificity. [17][18][19][20] Gas-phase actinide crown ether complexes, including of uranyl, present a means to elucidate factors that affect complexation and coordination, including geometric effects that may be supported by distinctive crown geometries. 18,20 In the present work we extend this general line of inquiry from mononuclear uranyl-crown complexes to dimeric uranyl complexes, with an aim to understand how crown ethers might act as bridging ligands and support novel bonding motifs such as cation-cation interactions.…”

Section: Introductionmentioning

confidence: 99%

Destruction of the Uranyl Moiety in a U(V) “Cation–Cation” Interaction

Jian

et al. 2019

Inorg. Chem.

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A gas-phase uranyl peroxide dimer supported by three 12-Crown-4 ether (12C4) ligands, [(UO2)2(O2)(12C4)3)] 2+ (A), was prepared by electrospray ionization. Density functional theory (DFT) indicates a structure with two terminal 12C4 and the third 12C4 bridging the uranium centers. Collision induced dissociation (CID) of A resulted in elimination of the bridging 12C4 to yield a uranyl peroxide dimer with two terminal donor ligands, [(12C4)(UO2)(O2)(UO2)(12C4)] 2+ (B). Remarkably, CID of B resulted in elimination of the bridging peroxide concomitant with reduction of U(VI) to U(V) in C, [(12C4)(UO2)(UO2)(12C4)] 2+. DFT indicates that in C there is direct interaction between the two UO2 + , which can thus be considered as a so-called cation-cation interaction (CCI). This formal CCI, induced by tetradentate 12C4 ligands, corresponds to destruction of the linear uranyl moieties and creation of bridging U-O-U oxo-bonds. Based on the structural rearrangement to achieve the structurally extreme CCI interaction, it is predicted to also be accessible for PaO2 + , but is less feasible for transuranic actinyls.

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“…Furthermore, the reduced 5f energy levels as well as the increasing orbital interaction between B 2pz and An 5f orbitals when traversing the actinide series from Th to Cm consequently, reveals the An-B bonds generally transit from strengthening to weakening at An = U, which has been a general trend in actinide chemistry emerging in accordance with the atomic number of the actinides. [64][65][66][67] Besides, the net consequence of these orbital interactions upon formation of the An(BH)24 complex can be basically viewed as the An valence orbitals being destabilized energetically in Fig. 8, leading to An cations in the complexes.…”

Section: Discussionmentioning

confidence: 99%

New theoretical insights into high-coordination-number complexes in actinides-centered borane

Zhang

Zou

et al. 2020

Nanoscale

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Periodic Trends in Actinyl Thio-Crown Ether Complexes

Cited by 29 publications

References 84 publications

Electronic Structures and Properties of Actinide‐Bimetal Compounds An₂O₂ (An=Th to Cf) and U₂E₂ (E=N, F, S)

Electronic Structures and Properties of Actinide‐Bimetal Compounds An₂O₂ (An=Th to Cf) and U₂E₂ (E=N, F, S)

Destruction of the Uranyl Moiety in a U(V) “Cation–Cation” Interaction

New theoretical insights into high-coordination-number complexes in actinides-centered borane

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Periodic Trends in Actinyl Thio-Crown Ether Complexes

Cited by 29 publications

References 84 publications

Electronic Structures and Properties of Actinide‐Bimetal Compounds An2O2 (An=Th to Cf) and U2E2 (E=N, F, S)

Electronic Structures and Properties of Actinide‐Bimetal Compounds An2O2 (An=Th to Cf) and U2E2 (E=N, F, S)

Destruction of the Uranyl Moiety in a U(V) “Cation–Cation” Interaction

New theoretical insights into high-coordination-number complexes in actinides-centered borane

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Electronic Structures and Properties of Actinide‐Bimetal Compounds An₂O₂ (An=Th to Cf) and U₂E₂ (E=N, F, S)

Electronic Structures and Properties of Actinide‐Bimetal Compounds An₂O₂ (An=Th to Cf) and U₂E₂ (E=N, F, S)