Unveiling the Covalency of Versatile Pu(III)–N bonds in a Unique Plutonium(III) Complex

IF 7.6 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Chemical Science Pub Date : 2025-05-06 DOI:10.1039/d5sc01808k

Zhuanling Bai, Madeline C. Martelles, Joseph M. Sperling, Thomas E. Albrecht

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引用次数: 0

Abstract

A trivalent plutonium-pyrizinyl-tetrazolate complex Na₂[Pu(Hdtp)(dtp)₂(H₂O)₄]·9H₂O (Pu_dtp, H₂dtp = 2,3-di-1H-tetrazol-5-ylpyrazine) was synthesized through metathesis reaction of plutonium bromide and Na₂(dtp)·2H₂O in water. This structure is particularly notable among complexes formed by trivalent f-elements and the dtp²⁻ ligand in aqueous media. In contrast to other trivalent f-elements, including all Ln³⁺ (with the exception of Pm³⁺) and Cm³⁺, preferentially coordinated with eight water molecules rather than the nitrogen donors of the dtp²⁻ ligand, Pu³⁺ exhibits a distinct affinity for nitrogen coordination. This observation provides strong evidence that the 5f electrons in Pu³⁺ are more delocalized than other studied trivalent f-elements, consistent with Hard-Soft Acid-Base theory. In Pu_dtp, three distinct Pu(III)–N bonds are present: one Pu(III)–N5 from pyrazinyl, one Pu(III)–N4 from the least electronegative nitrogen in the tetrazolate, and three Pu(III)–N1/N2/N3 from the most electronegative nitrogens in the tetrazolate. Experimental Pu(III)–N bond lengths, Wiberg bond indices (WBI), natural localized molecular orbitals (NLMO), Quantum Theory of Atoms in Molecules (QTAIM), and energy decomposition analysis (EDA), reveal a covalency trend: Pu(III)–N from the most electronegative nitrogen in tetrazolate > Pu(III)–N from the least electronegative nitrogen in tetrazolate > Pu(III)–N from pyrazinyl. This trend arises from the increased negative charge on the most electronegative nitrogen atoms in the tetrazolate ring, enhancing electrostatic Pu−N1/N2/N3 interactions. These stronger interactions promote better orbital overlap, leading to greater covalency compared to the less electronegative nitrogen in tetrazolate (Pu−N4) and the neutral pyrazinyl nitrogen (Pu−N5).

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揭示钚（III）配合物中多功能Pu(III) -N键的共价

以溴化钚和Na2（dtp）·2H2O为原料，在水中进行复分解反应，合成了三价钚-吡嗪基四氮酸盐配合物Na2[Pu(Hdtp)(dtp)2(H2O)4]·9H2O （Pu_dtp, H2dtp = 2,3-二- 1h -四氮-5-基吡嗪）。这种结构在水介质中由三价f元素和dtp2−配体形成的配合物中尤为明显。与其他三价f元素相比，包括所有Ln3+ （Pm3+除外）和Cm3+，优先与8个水分子而不是dtp2−配体的氮供体配位，Pu3+表现出明显的氮配位亲和力。这一观察结果提供了强有力的证据，证明Pu3+中的5f电子比其他已研究的三价f元素更具离域性，与硬-软酸碱理论相一致。在Pu_dtp中，存在三个不同的Pu(III) -N键：一个来自吡嗪基的Pu(III) -N5键，一个来自四氮酸盐中电负性最小的氮的Pu(III) -N4键，三个来自四氮酸盐中电负性最大的氮的Pu(III) -N1 /N2/N3键。实验Pu(III) -N键长、Wiberg键指数（WBI）、自然定域分子轨道（NLMO）、分子中原子量子理论（QTAIM）和能量分解分析（EDA）揭示了共价趋势：Pu(III) -N来自四氮酸盐中电负性最强的氮；四氮酸盐中电负性最小的氮的Pu(III) -N；Pu(III) -N来自吡嗪基。这种趋势是由于四氮酸盐环中电负性最强的氮原子上的负电荷增加，增强了静电Pu - N1/N2/N3相互作用。与电负性较小的四氮酸盐（Pu−N4）和中性吡嗪基氮（Pu−N5）相比，这些更强的相互作用促进了更好的轨道重叠，导致了更大的共价。

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来源期刊

Chemical Science CHEMISTRY, MULTIDISCIPLINARY-

CiteScore

14.40

自引率

4.80%

发文量

1352

审稿时长

2.1 months

期刊介绍： Chemical Science is a journal that encompasses various disciplines within the chemical sciences. Its scope includes publishing ground-breaking research with significant implications for its respective field, as well as appealing to a wider audience in related areas. To be considered for publication, articles must showcase innovative and original advances in their field of study and be presented in a manner that is understandable to scientists from diverse backgrounds. However, the journal generally does not publish highly specialized research.