Department of Chemistry , UiT - The Arctic University of Norway , N-9037 Tromsø , Norway.
Advanced Light Source , Lawrence Berkeley National Laboratory , Berkeley , California 94720-8229 , United States.
Inorg Chem. 2019 Feb 18;58(4):2798-2806. doi: 10.1021/acs.inorgchem.8b03391. Epub 2019 Feb 7.
A series of metal-metal bonded osmium corrole dimers, {Os[T pXPC]}, were synthesized in reasonably good yields (35-46%) via the interaction of the corresponding free-base meso-tris( p-X-phenyl)corroles (H[T pXPC], X = CF, H, CH, and OCH), Os(CO), and potassium carbonate in 1,2,4-trichlorobenzene under an inert atmosphere at 180 °C over several hours. The complexes are only the second class of Os corroles reported to date (the first being OsN corroles) and also the second class of metal-metal bonded metallocorrole dimers (the other being Ru corrole dimers). Comparison of the X-ray structures, redox potentials, and optical spectra of analogous Ru and Os corrole dimers, along with scalar-relativistic DFT calculations, has provided an experimentally calibrated account of relativistic effects in these complexes. Three of the Os corrole dimers (X = CF, H, and OCH) were analyzed with single-crystal X-ray diffraction analysis, revealing inversion-related corrole rings with eclipsed Os-N bonds and Os-Os distances of ∼2.24 Å that are ∼0.06 Å longer than the Ru-Ru distances in the analogous Ru corrole dimers. Interestingly, a comparison of scalar-relativistic and nonrelativistic DFT calculations indicates that this difference in metal-metal bond distance does not, in fact, reflect a differential relativistic effect. For a given corrole ligand, the Ru and Os corrole dimers exhibit nearly identical oxidation potentials but dramatically different reduction potentials, with the Os values ∼0.5 V lower relative to Ru, suggesting that whereas oxidation occurs in a ligand-centered manner, reduction is substantially metal-centered, which indeed was confirmed by scalar-relativistic calculations. The calculations further indicate that approximately a third of the ∼0.5 V difference in reduction potentials can be ascribed to relativity. The somewhat muted value of this relativistic effect appears to be related to the finding that reduction of an Os corrole dimer is not exclusively metal-based but that a significant amount of spin density is delocalized over to the corrole ligand; in contrast, reduction of an Ru corrole dimer occurs exclusively on the Ru-Ru linkage. For isoelectronic complexes, the Ru and Os corrole dimers exhibit substantially different UV-vis spectra. A key difference is a strong near-UV feature of the Os series, which in energy terms is blue-shifted by ∼0.55 V relative to the analogous feature of the Ru series. TDDFT calculations suggest that this difference may be related to higher-energy Os(5d)-based LUMOs in the Os case relative to analogous MOs for Ru.
一系列金属-金属键合的锇卟啉二聚体{Os[T pXPC]}通过相应的游离基中-三(对-X-苯基)卟啉(H[T pXPC],X = CF、H、CH 和 OCH)、Os(CO)和碳酸钾在惰性气氛中于 180°C 下在 1,2,4-三氯苯中反应数小时,以合理的产率(35-46%)合成。这些配合物是迄今为止报道的第二类 Os 卟啉(第一类为 OsN 卟啉),也是第二类金属-金属键合的金属卟啉二聚体(另一类为 Ru 卟啉二聚体)。与类似的 Ru 和 Os 卟啉二聚体的 X 射线结构、氧化还原电位和光学光谱进行比较,以及相对论密度泛函理论(DFT)计算,为这些配合物中的相对论效应提供了经过实验校准的解释。对三个 Os 卟啉二聚体(X = CF、H 和 OCH)进行了单晶 X 射线衍射分析,揭示了相关的反转卟啉环,具有重叠的 Os-N 键和约 2.24Å 的 Os-Os 距离,比类似的 Ru 卟啉二聚体中的 Ru-Ru 距离长约 0.06Å。有趣的是,相对论和非相对论 DFT 计算的比较表明,这种金属-金属键距离的差异实际上并不反映出不同的相对论效应。对于给定的卟啉配体,Ru 和 Os 卟啉二聚体表现出几乎相同的氧化电位,但还原电位却有显著差异,Os 值比 Ru 值低约 0.5V,表明氧化发生在配体中心,而还原则主要是金属中心,这确实通过相对论计算得到了证实。计算进一步表明,还原电位差异的约 0.5V 可归因于相对论。这种相对论效应的价值似乎相对较小,这似乎与以下发现有关,即 Os 卟啉二聚体的还原不是完全基于金属的,而是相当大的自旋密度分布在卟啉配体上;相比之下,Ru 卟啉二聚体的还原仅发生在 Ru-Ru 键上。对于等电子配合物,Ru 和 Os 卟啉二聚体表现出明显不同的紫外可见光谱。一个关键的区别是 Os 系列的强近紫外特征,其能量上相对于 Ru 系列的类似特征蓝移约 0.55V。TDDFT 计算表明,这种差异可能与 Os 情况下基于更高能量 Os(5d)的 LUMO 相对于 Ru 的类似 MO 有关。
