同核铈(III)和铈(IV)氮氧自由基配合物：对 4+氧化态的显著稳定化。

Homoleptic cerium(III) and cerium(IV) nitroxide complexes: significant stabilization of the 4+ oxidation state.

机构信息

P. Roy and Diana T. Vagelos Laboratories, Department of Chemistry, University of Pennsylvania , Philadelphia, Pennsylvania 19104, United States.

出版信息

Inorg Chem. 2013 Oct 7;52(19):11600-7. doi: 10.1021/ic401974t. Epub 2013 Sep 11.

DOI:10.1021/ic401974t

PMID:24024698

Abstract

Electrochemical experiments performed on the complex Ce(IV)[2-((t)BuNO)py]4, where 2-((t)BuNO)py = N-tert-butyl-N-2-pyridylnitroxide, indicate a 2.51 V stabilization of the 4+ oxidation state of Ce compared to [(n)Bu4N]2[Ce(NO3)6] in acetonitrile and a 2.95 V stabilization compared to the standard potential for the ion under aqueous conditions. Density functional theory calculations suggest that this preference for the higher oxidation state is a result of the tetrakis(nitroxide) ligand framework at the Ce cation, which allows for effective electron donation into, and partial covalent overlap with, vacant 4f orbitals with δ symmetry. The results speak to the behavior of CeO2 and related solid solutions in oxygen uptake and transport applications, in particular an inherent local character of bonding that stabilizes the 4+ oxidation state. The results indicate a cerium(IV) complex that has been stabilized to an unprecedented degree through tuning of its ligand-field environment.

摘要

电化学实验表明，与 [(n)Bu4N]2[Ce(NO3)6] 在乙腈中的 4+ 氧化态相比，配合物 Ce(IV)[2-((t)BuNO)py]4（其中 2-((t)BuNO)py = N-叔丁基-N-2-吡啶氮氧化物）中 Ce 的 4+ 氧化态稳定了 2.51 V，与水溶液中该离子的标准电势相比稳定了 2.95 V。密度泛函理论计算表明，这种对更高氧化态的偏好是由于 Ce 阳离子的四（氮氧化物）配体框架，它允许有效电子进入，并与具有 δ 对称性的空 4f 轨道部分共价重叠。这些结果涉及 CeO2 和相关固溶体在氧气吸收和传输应用中的行为，特别是键的固有局部性质稳定了 4+ 氧化态。结果表明，通过调节其配体场环境，一种铈(IV)配合物被稳定到了前所未有的程度。

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同核铈(III)和铈(IV)氮氧自由基配合物：对 4+氧化态的显著稳定化。

Homoleptic cerium(III) and cerium(IV) nitroxide complexes: significant stabilization of the 4+ oxidation state.

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